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Writing a boot loader in Assembly and C - Part 1

, 30 Oct 2013 CPOL
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How to boot a floppy image with your own hand written code in C and Assembly


I consider this article to be an introduction on writing a boot loader in C and Assembly and I did not want to get into performance comparisons against code written in C and Assembly in terms of writing a boot loader. In this article, I will only try to brief you about how to boot a floppy image by writing your own code and inject into the boot sector of a device (a boot loader program). During this process, I will break down the article into various sections. It felt hard to explain about computers, bootable devices, and how to write code in a single article so I have tried to do my best to explain the most common aspects of learning about computers and what is meant by booting. I tried to generalize the meaning and importance of each stage so that it may be easy to understand and remember too. In case you require more detailed explanation, you can browse through many articles provided on the internet.

What is the scope of the article?

I will limit the scope of the article to how to write program code and how to copy it to the boot sector of a floppy disk image, and then how to test the floppy disk if it boots with your program code or not, using an x86 emulator like bochs on Linux.

What I have not explained in the article

I have not explained why a boot loader cannot be written in other languages like assembly and the drawbacks in terms of writing a boot loader in one language when compared to another. As this is an introductory learning article on how to write boot code I don't want to bother you much about more advanced topics like speed, writing smaller code, etc.

How the article is organized

As far I am concerned I want to introduce in the article some of the basics and then follow that with code. So here is the break down of the contents in the order I brief you about how to write a boot loader.

  • Introduction to computers.
  • Introduction to programming tools.
  • Introduction to Number Systems.
  • Introduction to Bootable Devices.
  • Introduction to the development environment.
  • Introduction to microprocessor.
  • Writing code in an Assembler.
  • Writing code in a Compiler.
  • A mini-project to display rectangles.


  • This article really helps you a lot if you have prior programming experience in any language. Though this article seems to be fairly introductory, writing programs in Assembly and C can be a daunting task during boot time. If you are new to computer programming then I would suggest you to read a few tutorials on introducing programming and computer fundamentals and then come back to this article.
  • Throughout this article, I will be introducing you to various terminologies related to computers in the way of questions and answers. To be frank, I will write this article as if I am introducing this article to myself. So many question and answer kind of conversations has been put in to make sure that I will understand its importance and purpose in my every day life. Example: What do you mean by computers?, or Why do I need them because I am much smarter than them?

So, let us begin then....Smile | :)

Introduction to computers

First answer me. Do you like computers?

Yes, of course. Computers do not carry sex, age, or caste, they do not show dominance, that is why I like them, and they are very honest. Whatever I ask them to do, they do it for me and why should I ignore or hate them? In addition, I admire them as my best friend. It is an electronic age. You often hear this one-liner “I am addicted to computers”.

Why does anyone feel like the need to work with a computer in their lives?

Honestly, humans are much better than computers because we are humorous, Wink | Wink | ;) . Also we have a problem here when it comes to performing repetitive tasks or saving costs. Not every one of us is brilliant in this world to perform any kind of job within no time on a given day. Sometimes we are worried about other things and we give priorities to other things, that’s why we can not concentrate on utilizing every single second of a minute in doing our jobs successfully.

Saving our own costs, remind me of a term called simulation, which is commonly used in computing industry a lot. Let me present you with an example. Simulated learning environment for students who can't afford costly and very fragile equipments. Not only for students these days all costly equipments are being replaced by simulated environments so as to save the costs. How many times do you break a real equipment which costs millions of dollars with your testing and development? What I mean here is computer professionals write programs or software, which could give you a feel of the real time environment by sticking to one machine and through the software you can actually learn the things and then apply your knowledge to achieve better. It saves a lot of hardware and money for almost many. Also computers are also mainly used to automate a lot of hand work done during earlier days to provide a lot of services to humans to make their job much easier and a lot more faster these days. I guess that is enough for now Smile | Smile | :)

When I think about computers I sometimes actually think about electronic devices. They are the smallest and the most smartest devices available on the planet now. So, let us start with them.

What is an electronic device and what do I feel about them?

Let me explain you in a very generic way.. After all humans believed that humans can help each others only to a certain extent but not to the maximum. We have physical limits that make us the use of devices in our daily life. What I meant was you could not have a person dedicated to you and thinking about you for almost 24 hours a day and 365 days a year and then take necessary actions to make you feel batter. This lead to the invention of computers. I want a machine that could listen to me and do what I want it to do. I do not know if I am accurate about this or not but I will leave it to your own as to why you need a machine to help you rather than a human being. Are humans not smarter than computers? Come on...we are but I do not know sometimes machines are much faster than us. May be they look much smaller than us and we can carry them with our own hands and then make them do what we want. Hey, and do not take it in other ways...I just wanted to make it much simpler to you that is it.

What is a computer and is it much smarter than we are?

I hear them quite a lot of times in everyday life. A computer is an electronic device, which helps human’s as well as other electronic devices that depend upon information storage, retrieval, processing of data, which leads in providing more services in terms of simulation and decision-makings.

What does a typical computer look like?

What does each part do?

Monitor: We use a monitor to display information in visual form (pixel representation).

Why do we require a monitor?

A monitor displays information in visual form. I mean that it uses pixels to represent an image or object.

What is a pixel?

A pixel is the smallest unit in a computer through which a graphical image can be represented.

What is the use of a pixel?

Through a group of pixels computer represents an image or object. It is like a point that you draw on a paper with pen. But if you combine 100's of point you will be to provide a meaningful way to represent objects like text and expressions.

Let me provide you a visual representation of what a pixel is?

Now you might have got an idea as to why pixels are used in computing and what is their purpose.

A monitor uses a millions of pixels to provide pictorial representations of various objects to give the user a better experience along with speed. The portion of the monitor that displays the information is called the screen. Like a television screen, a computer screen can show still or moving pictures. No matter what human beings are, we try to imitate nature a lot and we call it creativity. Yes, this is true. Human beings in order to react to an event use voice and expressions (actions) which may be considered as the visual representations (actions) of the outcome against a particular event. Since a human has designed a computer and not all humans cant understand electrical signals they designed a special instrument called a monitor which actually responds to a particular event or all the events through visual representations.

  • Mouse: Remember me saying about visual representation of the outcome of an event earlier. Yes, we also use to give instructions visually to a computer through an input device called as mouse. The movement of a mouse is mapped to the X and Y co-ordinates of the screen of the monitor. Each monitor has a particular number of maximum number of columns and rows up to which it can represent the Income/outcome of an event.
  • Keyboard: Not all events seem humorous or easy to be triggered by mouse graphically. In order to overcome this limitation, we have invented an another device called keyboard through which typing a text can be really easy than mapping a text through a mouse.
  • Storage: In order to store the events triggered by a user, we need a device which can store what happened before or whats going to happen next and some temporary information and so on.

But why we need many storage devices instead of having a single one?

Well!!! the answer to it lies in terms of evolution of computers and how flexible these devices evolved are.

Examples of storage devices are:

  • Floppy disk
  • Hard disk
  • CD ROM and DVD
  • USB Disk

Where is the CPU?

These days the CPU is much buried inside a computer that it is not visible anymore. However, I will explain you about it.

CPU: This is called the brain of the computer. It contains various other parts that make it work like a human brain.

What are the different parts of a CPU?

I will list out only the most important ones here.

  • Microprocessor
  • RAM

What is a Microprocessor and what does it look like?

It is capable of understanding all the instructions given by a user and to proceed further to get the job done. You can think of it as a place in a computer where the given instructions are further broken down and then understood by a computer and then gives the desired output required by the user.

What is RAM?

This is like a work room for a computer. It uses this place like a garage to carry its temporary activities like creating its own temporary data to make decisions and proceed further.

Why doe a computer require a brain when humans tell the computer what to do and what not to do?

Yes you are right!!! It is the human beings that give instructions to a computer to follow our instructions, but we are much cleverer to the computers in terms of letting it to decide which is the best decision to take at what time and also to come up with the most optimum solution.

In this regards, we had to come up with one more component called as the CPU where the instructions are consumed from the user and then logical and mathematical decisions are taken.

What is the difference between RAM and the other storage devices specified earlier?

RAM also falls under the category of storage devices but it is used to store the data for only a certain period of time. When the computer is shutdown or restarted the data that is on RAM is lost. But the devices that I have mentioned under storage devices are used to store data for longer periods of time. If you write some data onto those devices, even after you shutdown or restart your machine, the data still remains.

So where and when can I start?

Wow, that is exciting...So I want to save a lot of money for others and me as well and want to help this world to become better and of course become famous too. I cant answer this question in a simple way like “Okay you get a computer and start writing programs on it and then sell it to your preferred customers and all the best”. What......Is that a joke ????? No! Not at all. Prior to helping others you should first help yourself in understanding computers a lot much before than to start writing programs on your own and then become a professional selling your programs to others and making your dream come true. The easiest way to start is learn them first. You are reading my article as you have access to internet and there are millions of tutorials out there in this electronic world which only help you to learn starting from what is an electronic device and how to use it. However, as far as writing your own programs on a computer, I seriously consider you to join into a course in computers may be at least for an year long and this should help you understand and write programs on a computer.

Okay...I got it and what is next?

I almost forgot one thing to tell you that computers are not like another world for humans. What I mean is they can understand humans and we can understand them too. I can talk to them and be friends to them? Great. Wait What I mean here is that you have to segregate your self into one of the two categories as mentioned below.

  • User
  • Programmer

Once you start gaining experience for yourself as a user then you can be a programmer too. You will also see that these two terms are almost overlapping. A User can be a programmer too and a programmer is a user too. However, for now, I want to make it as simple as possible.

  • Computer User: A person who uses computers to get his job done. He does not write programs but in fact he uses the programs written by others to get his job done in his Daily life. A person who is not into understanding the internal workings of a computer.
  • Computer programmer: A person who is a User and his main activities or interests falls under writing programs or software for other people or to the users including himself. So that they can be benefited by using them to get their job done.

I call a person to be technical in computing if a person writes programs on computers and has a desire to understand them in depth...other wise you can’t write programs.

  • Program: A set of instructions, which are obeyed by the computer to execute and give the desired result. Programmers write the instructions to get the desired output by the computer.
  • It is not easy to write those unless you grasp the internal workings of a computer at a very detailed level.

It is not easy to write those unless you grasp the internal workings of a computer at a very detailed level.

What are computer instructions?

In a very generic sense, an instruction is like a command to make a computer carry out an activity or an event. Let me explain you much further. Remember me about introducing the Central Processing Unit that it processes the instructions from user and gives us the desired output. Suppose say you want to add two numbers like 1 and 2 and the result you expect is 3 after adding.

  • Task1: You want this job to get it done by a human. Human to human way of solving the task. Person1 is asking person2: add two numbers say 1 and 2 and give me the result. Person2 replies: it is three.
  • Task2: You want this job to get it done by a computer. Human to computer interactions to perform this task. A user1 is asking a computer1: 1+2. computer1 responds: 3.

That’s it!!! Task2 is very simple. All you were doing was using mathematical expressions. I am a math’s major too and I know how to write mathematical instructions. Wait! So you mean that I can directly ask the computer what is 1+2 and I expect it to give me an answer. No. you cannot interact directly with a computer this way. You need a translator or a compiler.

Introduction to programming tools

Translator or compiler ... why two names?

Well a translator is a more generic word and a compiler is more inclined towards computers. In addition, there might be pure translators that do nothing but convert the instructions given by users into pure machine code. From my experience what I know about compilers are that they do not blindly convert the given instructions into machine code but instead they optimize it for better performance as well and much more.

What is a compiler?

Please remember that the computer only understands only machine code in binary format, which is a combination of 1’s or 0’s. However, when we say 1+2, a computer cannot understand what we mean by that. Therefore, we pass 1+2 to a compiler and the compiler will convert it into the architecture specific machine code.

What is machine code?

A code is only represented by 1’s and 0’s. In our case to add 1 and 2 the machine code might look like below:


It requires a lot of time to analyze the above code as to figure what was happening. Suppose say we are solving a puzzle which might have thousands of addition, subtraction and division operations. When those instructions are converted to machine code, you will have a book of 1s and 0s code which is quite tedious to figure out as to what was happening with those numbers. The above code is not the exact code, but what my point is can you remember the above code to just add two numbers. It is really a pain. In addition, what is we have a thousand instructions to execute. Would you remember 100’s of pages of 1’s and 0’s combinations. That’s why all we need is a compiler to convert our high-level instructions to respective machine code, which is a combination of 1’s and 0’s. We type 1+2 and pass it to the compiler, it will generate 11001000100101000100101010111111001000000 and executes, and further we perform the desired operation.

Why do I require a compiler? Can I not write machine code directly?

Yes, you can but it is quite tedious in terms of maintenance and if you have enough time try to Google on web for machine coding tutorial and then come back. At least in this article further I am not going to talk about it at all.

What else should I learn to start programming?

Number Systems and what happens when a computer is powered on.

Introduction to Number Systems

What is a number system in computers?

Everything in a computer operation is identified by numbers and computer identifies the numbers following one of the below numbering Systems.

What is a number?

A number can be treated as a combination of symbols, these symbols can be treated as digits, and the value of a number can be determined by the following. Count of the number of digits in a number.

  • The position of the digit in a number
  • Total number digits available with respect to its numbering system.

What are the type of number systems?

  • Decimal
  • Binary
  • Hexadecimal
  • Octal

I will ignore explaining about octal number system as its application in this article is not required at all.

Let us see what they are now.

Decimal: This is the most common number system we use in our day-to-day life. This is based on 10 digits and the digits range from 0 to 9. i.e., 0,1,2,3,4,5,6,7,8,9.


123 = 1*10^2 + 2*10^1+ 3*10^0
123.45 is represented as 1*10^2 + 2*10^1+ 3*10^0 + 4*10^-1 + 5*10^-2

Binary: This number system use only 1s and 0s to represent numbers. The base is defined as two. B denotes binary prefix.


101012 to base 2 = 10101B = 1×24+0×23+1×22+0×21+1×20 = 16+4+1= 21
101112 to base 2 = 10111B = 1×24+0×23+1×22+1×21+1×20 = 16+4+2+1= 23

Hexadecimal: This system uses digits from 0..9 and A..F. 0x denotes hexadecimal prefix


43 to base 16 = 0x43 = 16*4 + 3  = 67
3D to base 16 = 0x3D = 16*3 + 13 = 61

If you need more information about number systems, please browse the internet and Google for number systems. You will find a ton of materials.

Introduction to Bootable Devices

What happens when a typical computer is powered on?

Normally, when a computer is turned on the power button signals power supply to send proper voltage to computer and other components such as CPU, Monitor, Keyboard, Mouse. CPU initializes Basic Input Output System Read only Memory chip to load an executable program. Once the BIOS chip is initialized, it passes a special program to the CPU to execute called as BIOS and below are its functionality.

  • A BIOS is a special program that is embedded in BIOS chip.
  • The BIOS program is executed which in turn performs the following tasks.
  • Runs Power On self Test.
  • Checks the clocks and various buses available.
  • Checks system clock and hardware information in CMOS RAM
  • Verifies system settings, hardware settings pre-configured etc.,
  • Tests the attached hardware starting from devices like RAM, disk drives, optical drives, hardware drives and so on.
  • Depending upon the pre-configured information in BIOS Bootable devices information, it searches for a boot drive based on the information available in the settings and starts initializing it to proceed further.

Note: All x86 compatible CPUs start in an operating mode called as Real Mode during the booting.

What is a bootable device?

A device is bootable device if it contains a boot sector or boot block and bios reads that device by first loading the boot sector into memory (RAM) for execution and then proceeds further.

What is a sector?

A sector is a specifically sized division of a bootable disk. Usually a sector is of 512 bytes in size. I will explain you more about how a computer memory is measured and what are the various terminologies associated with it in the coming sections.

What is a boot sector?

A boot sector or a boot block is a region on a bootable device that contains machine code to be loaded into RAM by a computer system’s built-in firmware during its initialization. It is of 512 bytes on a floppy disk. You will come to know more about bytes in the coming sections.

How does a bootable device work?

Whenever a bootable device is initialized, bios searches and loads the 1st sector which is known as boot sector or boot block into the RAM and starts executing it. Whatever the code resides inside a boot sector is the first program you may edit to define the functionality of the computer for the rest of the time. What I mean here is you can write your own code and copy it to the boot sector to make the computer work in accordance with your requisites. The program code that you intend to write to the boot sector of a device is also called as boot loader.

What is a Boot Loader?

In computing, a boot loader is a special program that is executed each time a bootable device is initialized by the computer during its power on or reset. It is an executable machine code, which is very specific to the hardware architecture of the type of CPU or microprocessor.

How many types of microprocessor are available?

I will list out the following mainly.

  • 16 bit
  • 32 bit
  • 64 bit

Normally the more the number of bits the more memory space the programs are accessed to and the more performance they gain in terms of temporary storage etc. There are two major manufacturers of the microprocessors in business today and they are Intel and AMD. Through the rest of this article I will be referring only to Intel based family(x86) microprocessors.

What is the difference between Intel based microprocessors and AMD based microprocessors?

Each company has their own unique way of designing the microprocessors in terms of hardware and instruction sets used for the interactions.

Introduction to the development environment.

What is Real Mode?

Earlier in section “What happens when a computer boots”, I have mentioned that all x86 CPUs while booting from a device start in a real mode. It is very important to make a note of this while writing a boot code for any device. Real mode supports only 16-bit instructions. So the code you write to load into a boot record or boot sector of a device should be compiled to only 16 bit compatible code. In real mode, the instructions can work with a maximum of 16-bits at once, for example: a 16-bit CPU will have a particular instruction that can add two 16-bit numbers together in one CPU cycle, if it was necessary for a process to add together two 32-bit numbers, then it would take more cycles, that make use of 16-bit addition.

What is an instruction set?

A heterogeneous collection of entities that are very specific to the architecture (in terms of design) of the microprocessor that a user can use to interact with a microprocessor. I mean a collection of entities, which comprises of native data types, instructions, registers, addressing modes, memory architecture, interrupt and exception handling and external I/O. Usually a group of instructions are made common available for a family of microprocessor. The 8086 microprocessor is one of the family of 8086, 80286, 80386, 80486, Pentium, Pentium I, II, III …. also referred to as the X86 family. Through out this article I will refer to the instruction set referring to the x86 family of microprocessors.

How to write your own code to boot sector of a device?

To successfully achieve this task, we need to know about the below.

  • Operating system (GNU Linux)
  • Assembler (GNU Assembler)
  • Instruction set(x86 family)
  • Writing x86 Instructions on GNU Assembler for x86 Microprocessor.
  • Compiler (C programming language - optional)
  • Linker (GNU linker ld)
  • An x86 emulator like bochs used for our testing purposes.

What is an Operating System?

I will explain this in a very simple way. A big collection of various programs written by 100s and 1000s of professionals includes applications and utilities to help individuals and people across the globe. A part from technical stand point of view in general an operating system is mainly written to provide various applications to help people a lot in their daily life activities. Like connecting to internet, chatting, browsing the net, create files, save files, data, process data and a lot more. I still did not understand. What I mean here is that you may want to chat with your friends, you may want to watch news online, you may want to write some personal information to a file, you may want to watch some movies, you may want to calculate some mathematical equations, you may want to play games, you may want to do write programs and more…All these tasks can be achieved by means of an operating system. The job of an operating system is to provide with enough tools to help you and serve you. Some of the activities you want to multitask too and it is the job of the operating system to manage hardware and provide you the best experience it can to you.

Also, please make a note that, all modern operating systems operate in protected mode.

What are the different types of Operating System?

  • Windows
  • Linux
  • MAC

And more…

What is protected mode?

Unlike in Real mode, protected mode supports 32-bit instructions. Do not worry about it now a lot, as we are not much bothered about how an operating system works etc.

What is an Assembler?

An assembler converts the instructions given by a user to a machine code.

Even a compiler does the same...doesn't it?

At a higher-level yes...but it is actually the assembler which is embedded inside a compiler does this activity.

Then why can't a compiler generate machine code directly?

The primary job of a compiler mainly falls into converting the instructions written by a user into an intermediate set of instructions called as assembly language instructions. Then the assembler will consume these instructions and will convert into the respective machine code.

Why do I need an operating system to write a code for boot sector?

Right now, I do not want to get into very detailed level of explanation but let me explain in terms of the scope of this article. Well! Earlier I mentioned that in order to write instructions that can be understood by a microprocessor, we need compiler and this compiler is developed as a utility in Operating Systems. I told you that Operating Systems are designed to help people providing various utilities and compilers are one of the utilities too.

Which Operating System may I use?

I have written programs on Ubuntu Operating system to boot from a floppy device so I would recommend Ubuntu for this article.

Which compiler should I use?

I have written programs using GNU GCC compiler and I will how to compile the code using the same. How do I test a hand written code to a boot sector of a device? I will introduce you to an x86 emulator which can help us to a great levels without letting us to restart the computer each time we edit the boot sector of the device.

Introduction to microprocessor

In order to learn programming a microprocessor, first we need to learn how to use registers.

What are registers?

Registers are like utilities of a microprocessor to store data temporarily and manipulate it as per our requirements. Suppose say if the user wants to add 3 with 2, the user asks the computer to store number 3 in one register and number 2 in more register and then add the contents of the these two registers and the result is placed in another register by the CPU which is the output that we desire to see. There are four types of registers and are listed below.

  • General purpose registers
  • Segment registers
  • Stack registers
  • Index registers

Let me brief you about each of the types.

General purpose registers: These are used to store temporary data required by the program during its lifecycle. Each of these registers is 16 bit wide or 2 bytes long.

  • AX - the accumulator register
  • BX - the base address register
  • CX - the count register
  • DX - the data register

Segment Registers: To represent a memory address to a microprocessor, there are two terms we need to be aware of:

  • Segment: It is usually the beginning of the block of a memory.
  • Offset: It is the index of memory block onto it.

Example: Suppose say, there is a byte whose value is 'X' that is present on a block of memory whose start address is 0x7c00 and the byte is located at the 10th position from the beginning. In this situation, We represent segment as 0x7c00 and the offset as 10.
The absolute address is 0x7c00 + 10.

There are four categories that I wanted to list out.

  • CS - code segment
  • SS - stack segment
  • DS - data segment
  • ES - extended segment

But there is always a limitation with these registers. You cannot directly assign an address to these registers. What we can do is, copy the address to a general purpose registers and then copy the address from that register to the segment registers. Example: To solve the problem of locating byte 'X', we do the following way

movw $0x07c0, %ax
movw %ax    , %ds
movw (0x0A) , %ax 

In our case what happens is

  • set 0x07c0 * 16 in AX
  • set DS = AX = 0x7c00
  • set 0x7c00 + 0x0a to ax

I will describe about the various addressing modes that we need to understand while writing programs.

Stack Registers:

  • BP - base pointer
  • SP - stack pointer

Index Registers:

  • SI - source index register.
  • DI - destination index register.
  • AX: CPU uses it for arithmetic operations.
  • BX: It can hold the address of a procedure or variable (SI, DI, and BP can also). And also perform arithmetic and data movement.
  • CX: It acts as a counter for repeating or looping instructions.
  • DX: It holds the high 16 bits of the product in multiply (also handles divide operations).
  • CS: It holds base location for all executable instructions in a program.
  • SS: It holds the base location of the stack.
  • DS: It holds the default base location for variables.
  • ES: It holds additional base location for memory variables.
  • BP: It contains an assumed offset from the SS register. Often used by a subroutine to locate variables that were passed on the stack by a calling program.
  • SP: Contains the offset of the top of the stack.
  • SI: Used in string movement instructions. The source string is pointed to by the SI register.
  • DI: Acts as the destination for string movement instructions.

What is a bit?

In computing, a bit is the smallest unit where data can be stored. Bits store data in the form of binary. Either a 1(On) or 0(Off).

More about registers:

The registers are further divided as below following left to right order or bits:

  • AX: The first 8 bits of AX is identified as AL and the last 8 bits is identified as AH
  • BX: The first 8 bits of BX is identified as BL and the last 8 bits is identified as BH
  • CX: The first 8 bits of CX is identified as CL and the last 8 bits is identified as CH
  • DX: The first 8 bits of DX is identified as DL and the last 8 bits is identified as DH

How to access BIOS functions?

BIOS provide a set of functions that let us draw the attention of the CPU. One will be able to access BIOS features through interrupts.

What are interrupts?

To interrupt the ordinary flow of a program and to process events that require prompt response we use interrupts. The hardware of a computer provides a mechanism called interrupts to handle events. For example, when a mouse is moved, the mouse hardware interrupts the current program to handle the mouse movement (to move the mouse cursor, etc.) Interrupts cause control to be passed to an interrupt handler. Interrupt handlers are routines that process the interrupt. Each type of interrupt is assigned an integer number. At the beginning of physical memory, a table of interrupt vectors resides that contain the segmented addresses of the interrupt handlers. The number of interrupt is essentially an index into this table. We can also called as the interrupt as a service offered by BIOS.

Which interrupt service are we going to use in our programs?

Bios interrupt 0x10.

Writing code in an Assembler

What are the various Data types available in GNU Assembler?

A group of bits used in representing a unit to frame various data types.

What is a data type?

A data type is used to identify the characteristic of a data. Various data types are as below.

  • byte
  • word
  • int
  • ascii
  • asciz

byte: It is eight bits long. A byte is considered as the smallest unit on a computer onto which data can be stored through programming.

word: It is a unit of data that is 16 bits long.

What is an int?

An int is a data type that represents data of 32 bits long. Four bytes or two words constitute an int.

What is an ascii?

A data type to represent a group of bytes with out a null terminator.

What is an asciz?

A data type to represent a group of bytes terminated with a null character in the end.

How do I generate code for real mode through an assembler?

When the CPU starts in Real Mode (16-bit), all we can do while booting from a device is to utilize the built in functions provided by the BIOS to proceed further. What I mean here is we can utilize the functions of BIOS to write our own boot loader code, and then dump into onto the boot sector of the device, and then boot it. Let us see how to write a small piece of code in assembler that generates 16-bit CPU code through GNU Assembler.

Example: test.S  

.code16                   #generate 16-bit code
.text                     #executable code location
     .globl _start;
_start:                   #code entry point
     . = _start + 510     #mov to 510th byte from 0 pos
     .byte 0x55           #append boot signature
     .byte 0xaa           #append boot signature

Let me explain each statement in the code above.

  • .code16: It is a directive or a command given to an assembler to generate 16-bit code rather than 32-bit ones. Why is this hint necessary? Remember that you will be using an operating system to utilize an assembler and a compiler to write boot loader code. However, I have also mentioned that an operating system works in 32 bit protected mode. So when you utilize assembler on a protected mode operating system, it’s configured by default to produce 32-bit code rather than 16-bit code, which does not serve the purpose, as we need 16-bit code. To avoid assembler and compilers generating 32-bit code, we use this directive.
  • .text: The .text section contains the actual machine instructions, which make up your program.
  • .globl _start: .global <symbol> makes the symbol visible to linker. If you define symbol in your partial program, its value is made available to other partial programs that are linked with it. Otherwise, symbol takes its attributes from a symbol of the same name from another file linked into the same program.
  • _start: Entry to the main code and _start is the default entry point for the linker.
  • . = _start + 510: traverse from beginning through 510th byte
  • .byte 0x55: It is the first byte identified as a part of the boot signature.(511th byte)
  • .byte 0xaa: It is the last byte identified as a part of the boot signature.(512th byte )

How to compile an assembly program?

Save the code as test.S file. On the command prompt type the below:

  • as test.S -o test.o
  • ld –Ttext 0x7c00 --oformat=binary test.o –o test.bin

What does the above commands means to us anyway?

  • as test.S –o test.o: this command converts the given assembly code into respective object code which is an intermediate code generated by the assembler before converting into machine code.
  • The --oformat=binary switch tells the linker you want your output file to be a plain binary image (no startup code, no relocations, ...).
  • The –Ttext 0x7c00 tells the linker you want your "text" (code segment) address to be loaded to 0x7c00 and thus it calculates the correct address for absolute addressing.

What is a boot signature?

Remember earlier I was briefing about boot record or boot sector loaded by BIOS program. How does BIOS recognize if a device contains a boot sector or not? To answer this, I can tell you that a boot sector is 512 bytes long and in 510th byte a symbol 0x55 is expected and in the 511th byte another symbol 0xaa is expected. So I verifies if the last two bytes of a boot sector are 0x55 and 0xaa and if it is then it identifies that sector as a boot sector and proceeds execution of the boot sector code or else it throws an error that the device is not bootable. Using a hexadecimal editor you can view the contents of the binary file in a more readable way and below is the snapshot for your reference when you view the file using the hexedit tool.

How to copy the executable code to a bootable device and then test it?

To create a floppy disk image of 1.4mb size, type the following on the command prompt.

  • dd if=/dev/zero of=floppy.img bs=512 count=2880

To copy the code to the boot sector of the floppy disk image file, type the following on the command prompt.

  • dd if=test.bin of=floppy.img

To test the program type the following on the command prompt

  • bochs

If bochs is not installed then you may type the below commands

  • sudo apt-get install bochs-x
Sample bochsrc.txt file
megs: 32
#romimage: file=/usr/local/bochs/1.4.1/BIOS-bochs-latest, address=0xf0000
#vgaromimage: /usr/local/bochs/1.4.1/VGABIOS-elpin-2.40
floppya: 1_44=floppy.img, status=inserted
boot: a
log: bochsout.txt
mouse: enabled=0 

You should see a typical emulating window of bochs as below.


Now if you view the test.bin file in a hexadecimal editor you will see the boot signature is placed at the end of the 510th byte and here is the screenshot for your reference.


Nothing has just happened as we did not write anything to display on the screen in our code. So you only see a message “Booting from Floppy”. Let us see a few more examples on writing assembly code on an assembler. 

Example: test2.S    
.code16                    #generate 16-bit code
.text                      #executable code location
     .globl _start;
_start:                    #code entry point

     movb $'X' , %al       #character to print
     movb $0x0e, %ah       #bios service code to print
     int  $0x10            #interrupt the cpu now

     . = _start + 510      #mov to 510th byte from 0 pos
     .byte 0x55            #append boot signature
     .byte 0xaa            #append boot signature 

After typing the above, save to test2.S and then compile as instructed before by changing the source file name. When you compile and successfully copy this code to the boot sector and run bochs you should see the below screen. On the command prompt type bochs to see the result and you should see the letter ‘X’ on the screen as shown in the below screenshot.



if viewed in a hexadecimal editor, you will see that the character 'X' is in the second position from the start address.

Now lets do something different like printing a text onto the screen.

Example: test3.S  
.code16                  #generate 16-bit code
.text                    #executable code location
     .globl _start;

_start:                  #code entry point

     #print letter 'H' onto the screen
     movb $'H' , %al
     movb $0x0e, %ah
     int  $0x10

     #print letter 'e' onto the screen
     movb $'e' , %al
     movb $0x0e, %ah
     int  $0x10

     #print letter 'l' onto the screen
     movb $'l' , %al
     movb $0x0e, %ah
     int  $0x10

     #print letter 'l' onto the screen
     movb $'l' , %al
     movb $0x0e, %ah
     int  $0x10

     #print letter 'o' onto the screen
     movb $'o' , %al
     movb $0x0e, %ah
     int  $0x10

     #print letter ',' onto the screen
     movb $',' , %al
     movb $0x0e, %ah
     int  $0x10

     #print space onto the screen
     movb $' ' , %al
     movb $0x0e, %ah
     int  $0x10

     #print letter 'W' onto the screen
     movb $'W' , %al
     movb $0x0e, %ah
     int  $0x10

     #print letter 'o' onto the screen
     movb $'o' , %al
     movb $0x0e, %ah
     int  $0x10

     #print letter 'r' onto the screen
     movb $'r' , %al
     movb $0x0e, %ah
     int  $0x10

     #print letter 'l' onto the screen
     movb $'l' , %al
     movb $0x0e, %ah
     int  $0x10

     #print letter 'd' onto the screen
     movb $'d' , %al
     movb $0x0e, %ah
     int  $0x10

     . = _start + 510      #mov to 510th byte from 0 pos
     .byte 0x55            #append boot signature
     .byte 0xaa            #append boot signature 

Save it as test3.S. When you compile and successfully copy this code to the boot sector and run bochs you should see the below screen.

Observation: we do something more different than the previous programs.  

Let us write an assembly program to print the letters “Hello, World” onto the screen.  

We will also try to define functions and macros through which we will try to print the string.

Example: test4.S     
#generate 16-bit code

#hint the assembler that here is the executable code located
.globl _start;
#boot code entry
      jmp _boot                           #jump to boot code
      welcome: .asciz "Hello, World\n\r"  #here we define the string

     .macro mWriteString str              #macro which calls a function to print a string
          leaw  \str, %si
          call .writeStringIn

     #function to print the string
          orb  %al, %al
          jz   .writeStringOut
          movb $0x0e, %ah
          int  $0x10
          jmp  .writeStringIn

     mWriteString welcome

     #move to 510th byte from the start and append boot signature
     . = _start + 510
     .byte 0x55
     .byte 0xaa  

Save it as test4.S. When you compile and successfully copy this code to the boot sector and run bochs you should see the below screen.

Well!!! If you did understand what I have done and you were able to write similar program then congratulations again!


What is a function?

A function is a block of code that has a name and it has a property that it is reusable.

What is a macro?

A macro is a fragment of code, which has been given a name. Whenever the name is used, it is replaced by the contents of the macro.

What is the difference between a macro and a function in terms of syntax?

To call a function we use the below syntax.

  • push <argument>
  • call <function name>

To call a macro we use the below syntax

  • macroname <argument>

But the calling and usage syntax of the macro is very simple when compared to that of a function. So I preferred to write a macro and use it instead of calling a function in the main code. You can refer to more materials online as to how to write assembly code on GNU Assembler.

Writing code in a C-Compiler

What is C?

In computing, C is a general-purpose programming language initially developed by Dennis Ritchie between 1969 and 1973 at AT&T Bell Labs.

Why use C? A machine dependent language but programs written in C are usually small and fast to execute. The language includes low-level features that are normally available only in assembly or machine language. C is a structured programming language.

Why do I need to write code in C?

Well if you want to write smaller programs and want them to be really fast then go for it.

What do I need to write code in C language?

Well, we will be using GNU C compiler called gcc to write C code.

How to write programs in GCC compiler in C?

Let us write a program to see how it looks like.

Example: test.c
__asm__("jmpl $0x0000, $main\n");

void main() {
File: test.ld
    . = 0x7C00;
    .text : AT(0x7C00)
    .sig : AT(0x7DFE)

How to compile a C program? On the command prompt type the below:

  • gcc -c -g -Os -march=i686 -ffreestanding -Wall -Werror test.c -o test.o
  • ld -static -Ttest.ld -nostdlib --nmagic -o test.elf test.o
  • objcopy -O binary test.elf test.bin

What does the above commands means to us anyway?

  • gcc -c -g -Os -march=i686 -ffreestanding -Wall -Werror test.c -o test.o:
  • This command converts the given C code into respective object code which is an intermediate code generated by the compiler before converting into machine code.

What does each flag mean?

  • -c: It is used to compile the given source code without linking.
  • -g: Generates debug information to be used by GDB debugger.
  • -Os: optimization for code size
  • -march: Generates code for the specific CPU architecture (in our case i686)
  • -ffreestanding: A freestanding environment is one in which the standard library may not exist, and program startup may not necessarily be at ‘main’.
  • -Wall: Enable all compiler's warning messages. This option should always be used, in order to generate better code.
  • -Werror: Enable warnings being treated as errors
  • test.c: input source file name
  • -o: generate object code
  • test.o: output object code file name.

With all the above combinations of flags to the compiler, we try to generate object code which helps us in identifying errors, warnings and also produce much efficient code for the type of CPU. If you do not specify march=i686 it generates code for the machine type you have or else it on order to port it always better to specify which type of CPU are you targeting for.

  • ld -static -Ttest.ld -nostdlib --nmagic test.elf -o test.o:

This is the command to invoke linker from the command prompt and I have explained below what are we trying to do with the linker.

What does each flag mean?

  • -static: Do not link against shared libraries.
  • -Ttest.ld: This feature permits the linker to follow commands from a linker script.
  • -nostdlib: This feature permits the linker to generate code by linking no standard C library startup functions.
  • --nmagic:This feature permits the linker to generate code without _start_SECTION and _stop_SECTION codes.
  • test.elf: input file name(platform dependent file format to store executables Windows: PE, Linux: ELF)
  • -o: generate object code
  • test.o: output object code file name.

What is a linker?

It is the final stage of compilation. The ld(linker) takes one or more object files or libraries as input and combines them to produce a single (usually executable) file. In doing so, it resolves references to external symbols, assigns final addresses to procedures/functions and variables, and revises code and data to reflect new addresses (a process called relocation).

Also remember that we have no standard libraries and all fancy functions to use in our code.

  • objcopy -O binary test.elf test.bin

This command is used to generate platform independent code. Note that Linux stores executables in a different way than windows. Each have their own way storing files but we are just developing a small code to boot which does not depend on any operating system at the moment. So we are dependent on neither of those as we don't require an Operating system to run our code during boot time.

Why use assembly statements inside a C program?

In Real Mode, the BIOS functions can be easily accessed through software interrupts, using Assembly language instructions. This has lead to the usage of inline assembly in our C code.

How to copy the executable code to a bootable device and then test it?

To create a floppy disk image of 1.4mb size, type the following on the command prompt.

  • dd if=/dev/zero of=floppy.img bs=512 count=2880

To copy the code to the boot sector of the floppy disk image file, type the following on the command prompt.

  • dd if=test.bin of=floppy.img

To test the program type the following on the command prompt

  • bochs

You should see a typical emulating window of bochs as below.

Observation: Nothing has just happened as we did not write anything to display on the screen in our code. So you only see a message “Booting from Floppy”. Congrats!!!

  • We use __asm__ keyword to embed assembly language statements into a C program. This keyword hints the compiler to recognize that it is an assembly instruction given by the user.
  • We also use __volatile__ to hint the assembler not to modify our code and let it as it is.

This way of embedding assembly code inside C code is called as inline assembly.

Let us see a few more examples on writing code on a Compiler.

Let us write an assembly program to print the letter ‘X’ onto the screen.

Example: test2.c

__asm__("jmpl $0x0000, $main\n");

void main() {
     __asm__ __volatile__ ("movb $'X'  , %al\n");
     __asm__ __volatile__ ("movb $0x0e, %ah\n");
     __asm__ __volatile__ ("int $0x10\n");

After typing the above, save to test2.c and then compile as instructed before by changing the source file name. When you compile and successfully copy this code to the boot sector and run bochs you should see the below screen. On the command prompt type bochs to see the result and you should see the letter ‘X’ on the screen as shown in the below screen shot.

Now, let us write a c program to print the letters “Hello, World” onto the screen.

We will also try to define functions and macros through which we will try to print the string.

Example: test3.c

/*generate 16-bit code*/
/*jump boot code entry*/
__asm__("jmpl $0x0000, $main\n");

void main() {
     /*print letter 'H' onto the screen*/
     __asm__ __volatile__("movb $'H' , %al\n");
     __asm__ __volatile__("movb $0x0e, %ah\n");
     __asm__ __volatile__("int  $0x10\n");

     /*print letter 'e' onto the screen*/
     __asm__ __volatile__("movb $'e' , %al\n");
     __asm__ __volatile__("movb $0x0e, %ah\n");
     __asm__ __volatile__("int  $0x10\n");

     /*print letter 'l' onto the screen*/
     __asm__ __volatile__("movb $'l' , %al\n");
     __asm__ __volatile__("movb $0x0e, %ah\n");
     __asm__ __volatile__("int  $0x10\n");

     /*print letter 'l' onto the screen*/
     __asm__ __volatile__("movb $'l' , %al\n");
     __asm__ __volatile__("movb $0x0e, %ah\n");
     __asm__ __volatile__("int  $0x10\n");

     /*print letter 'o' onto the screen*/
     __asm__ __volatile__("movb $'o' , %al\n");
     __asm__ __volatile__("movb $0x0e, %ah\n");
     __asm__ __volatile__("int  $0x10\n");

     /*print letter ',' onto the screen*/
     __asm__ __volatile__("movb $',' , %al\n");
     __asm__ __volatile__("movb $0x0e, %ah\n");
     __asm__ __volatile__("int  $0x10\n");

     /*print letter ' ' onto the screen*/
     __asm__ __volatile__("movb $' ' , %al\n");
     __asm__ __volatile__("movb $0x0e, %ah\n");
     __asm__ __volatile__("int  $0x10\n");

     /*print letter 'W' onto the screen*/
     __asm__ __volatile__("movb $'W' , %al\n");
     __asm__ __volatile__("movb $0x0e, %ah\n");
     __asm__ __volatile__("int  $0x10\n");

     /*print letter 'o' onto the screen*/
     __asm__ __volatile__("movb $'o' , %al\n");
     __asm__ __volatile__("movb $0x0e, %ah\n");
     __asm__ __volatile__("int  $0x10\n");

     /*print letter 'r' onto the screen*/
     __asm__ __volatile__("movb $'r' , %al\n");
     __asm__ __volatile__("movb $0x0e, %ah\n");
     __asm__ __volatile__("int  $0x10\n");

     /*print letter 'l' onto the screen*/
     __asm__ __volatile__("movb $'l' , %al\n");
     __asm__ __volatile__("movb $0x0e, %ah\n");
     __asm__ __volatile__("int  $0x10\n");

     /*print letter 'd' onto the screen*/
     __asm__ __volatile__("movb $'d' , %al\n");
     __asm__ __volatile__("movb $0x0e, %ah\n");
     __asm__ __volatile__("int  $0x10\n");

Now save the above code as test3.c and then follow the compilation instructions given by changing the input source file name and follow the instructions given to copy the compiled code to the boot sector of the floppy. Now observe the result. You should see the below screen output if everything was fine.

Let us write a C program to print the letters “Hello, World” onto the screen.

We will also try to define function through which we will try to print the string.

Example: test4.c

/*generate 16-bit code*/
/*jump boot code entry*/
__asm__("jmpl $0x0000, $main\n");

/* user defined function to print series of characters terminated by null character */
void printString(const char* pStr) {
     while(*pStr) {
          __asm__ __volatile__ (
               "int $0x10" : : "a"(0x0e00 | *pStr), "b"(0x0007)

void main() {
     /* calling the printString function passing string as an argument */
     printString("Hello, World");

Now save the above code as test3.c and then follow the compilation instructions given by changing the input source file name and follow the instructions given to copy the compiled code to the boot sector of the floppy. Now observe the result. You should see the below screen output if everything was fine.

I wanted to bring to your note one point. All we are trying to do is just converting the assembly programs written earlier into C programs by way of learning. By now you should be comfortable in writing programs in Assembly and C and also well aware of how to compile and then test them.

Now we will move onto writing loops and making them work inside a function and also see more bios services.

A mini-project to display rectangles

Now let us move onto something more big…like displaying graphics.

Example: test5.c

/* generate 16 bit code                                                 */
/* jump to main function or program code                                */
__asm__("jmpl $0x0000, $main\n");

#define MAX_COLS     320 /* maximum columns of the screen               */
#define MAX_ROWS     200 /* maximum rows of the screen                  */

/* function to print string onto the screen                             */
/* input ah = 0x0e                                                      */
/* input al = <character to print>                                      */
/* interrupt: 0x10                                                      */
/* we use interrupt 0x10 with function code 0x0e to print               */
/* a byte in al onto the screen                                         */
/* this function takes string as an argument and then                   */
/* prints character by character until it founds null                   */
/* character                                                            */
void printString(const char* pStr) {
     while(*pStr) {
          __asm__ __volatile__ (
               "int $0x10" : : "a"(0x0e00 | *pStr), "b"(0x0007)

/* function to get a keystroke from the keyboard                        */
/* input ah = 0x00                                                      */
/* input al = 0x00                                                      */
/* interrupt: 0x10                                                      */
/* we use this function to hit a key to continue by the                 */
/* user                                                                                    */
void getch() {
     __asm__ __volatile__ (
          "xorw %ax, %ax\n"
          "int $0x16\n"

/* function to print a colored pixel onto the screen                    */
/* at a given column and at a given row                                 */
/* input ah = 0x0c                                                      */
/* input al = desired color                                             */
/* input cx = desired column                                            */
/* input dx = desired row                                               */
/* interrupt: 0x10                                                      */
void drawPixel(unsigned char color, int col, int row) {
     __asm__ __volatile__ (
          "int $0x10" : : "a"(0x0c00 | color), "c"(col), "d"(row)

/* function to clear the screen and set the video mode to               */
/* 320x200 pixel format                                                 */
/* function to clear the screen as below                                */
/* input ah = 0x00                                                      */
/* input al = 0x03                                                      */
/* interrupt = 0x10                                                     */
/* function to set the video mode as below                              */
/* input ah = 0x00                                                      */
/* input al = 0x13                                                      */
/* interrupt = 0x10                                                     */
void initEnvironment() {
     /* clear screen                                                    */
     __asm__ __volatile__ (
          "int $0x10" : : "a"(0x03)
     __asm__ __volatile__ (
          "int $0x10" : : "a"(0x0013)

/* function to print rectangles in descending order of                  */
/* their sizes                                                          */
/* I follow the below sequence                                          */
/* (left, top)     to (left, bottom)                                    */
/* (left, bottom)  to (right, bottom)                                   */
/* (right, bottom) to (right, top)                                      */
/* (right, top)    to (left, top)                                       */
void initGraphics() {
     int i = 0, j = 0;
     int m = 0;
     int cnt1 = 0, cnt2 =0;
     unsigned char color = 10;

     for(;;) {
          if(m < (MAX_ROWS - m)) {
          if(m < (MAX_COLS - m - 3)) {

          if(cnt1 != cnt2) {
               cnt1  = 0;
               cnt2  = 0;
               m     = 0;
               if(++color > 255) color= 0;

          /* (left, top) to (left, bottom)                              */
          j = 0;
          for(i = m; i < MAX_ROWS - m; ++i) {
               drawPixel(color, j+m, i);
          /* (left, bottom) to (right, bottom)                          */
          for(j = m; j < MAX_COLS - m; ++j) {
               drawPixel(color, j, i);

          /* (right, bottom) to (right, top)                            */
          for(i = MAX_ROWS - m - 1 ; i >= m; --i) {
               drawPixel(color, MAX_COLS - m - 1, i);
          /* (right, top)   to (left, top)                              */
          for(j = MAX_COLS - m - 1; j >= m; --j) {
               drawPixel(color, j, m);
          m += 6;
          if(++color > 255)  color = 0;

/* function is boot code and it calls the below functions               */
/* print a message to the screen to make the user hit the               */
/* key to proceed further and then once the user hits then              */
/* it displays rectangles in the descending order                       */
void main() {
     printString("Now in bootloader...hit a key to continue\n\r");

Now save the above code as test5.c and then follow the compilation instructions given by changing the input source file name and follow the instructions given to copy the compiled code to the boot sector of the floppy.

Now observe the result. You should see the below screen output if everything was fine.

Now hit a key to see what will happen further.


If you closely look at the contents of the executable, you will observe that we were almost running out of space. As boot sector is only 512 bytes, we were able to embed only few functions into our program like intializing the environment and then printing colored rectangles but not more than that because it requires more than 512 bytes of space. Below is the snapshot for your reference.

That’s all for this article. Have fun and write more programs to explore the real mode and you will observe that it is real fun programming in real mode using bios Interrupts. In the next article, I will try to explain about Addressing modes used to access data, reading a floppy disk and its architecture and also why a boot loader is mostly written in Assembly than C and what are the constraints in writing a bootloader in C in terms of Code Generation Smile | :)  


This article, along with any associated source code and files, is licensed under The Code Project Open License (CPOL)


About the Author

Software Developer
United States United States
Ashakiran is from Hyderabad, India and currently working as a Software Engineer in USA. He is a hobbyist programmer and enjoys writing code in C/C++ and Assembly. His biggest passion is into the world of Operating Systems Design and Development.
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Comments and Discussions

QuestionTest4.c - Runtime Error PinmemberRoNaK gOhel7-Dec-14 22:47 
Questioncompile time error PinmemberMember 1089326028-Aug-14 10:34 
AnswerRe: compile time error PinmemberAshakiranBhatter31-Aug-14 13:11 
GeneralGood, but... PinmemberFIorian Schneidereit1-Aug-14 23:56 
GeneralRe: Good, but... PinmemberAshakiranBhatter31-Aug-14 13:11 
QuestionLinking error PinmemberMember 102893163-Apr-14 0:36 
AnswerRe: Linking error PinmemberAshakiranBhatter9-Apr-14 7:45 
Questiondd problems?! [modified] PinmemberNickolakis21-Mar-14 6:45 
AnswerRe: dd problems?! PinmemberAshakiranBhatter21-Mar-14 18:21 
Questionlink error! PinmemberPp______Pp16-Mar-14 2:01 
AnswerRe: link error! PinmemberPp______Pp16-Mar-14 2:16 
GeneralRe: link error! PinmemberAshakiranBhatter16-Mar-14 8:33 
GeneralRe: link error! PinmemberPp______Pp16-Mar-14 17:43 
QuestionCongrats! PinmemberRye Salvador11-Jan-14 4:03 
AnswerRe: Congrats! [modified] PinmemberAshakiranBhatter11-Jan-14 8:33 
GeneralRe: Congrats! PinmemberRye Salvador12-Jan-14 22:41 
GeneralRe: Congrats! PinmemberAshakiranBhatter13-Jan-14 7:44 
GeneralRe: Congrats! PinmemberRye Salvador13-Jan-14 16:19 
GeneralRe: Congrats! Pinmembercwt880513-Jan-14 21:44 
AnswerRe: Congrats! PinmemberMember 1069145525-Nov-14 11:51 
GeneralRe: Congrats! PinmemberRye Salvador28-Nov-14 4:09 
Questionlinker error message PinmemberRye Salvador5-Jan-14 16:59 
AnswerRe: linker error message PinmemberAshakiranBhatter5-Jan-14 17:51 
GeneralRe: linker error message [modified] PinmemberRye Salvador6-Jan-14 4:27 
QuestionRun this in a real machine. PinmemberMember 1047888520-Dec-13 2:02 
AnswerRe: Run this in a real machine. PinmemberAshakiranBhatter1-Jan-14 1:17 
GeneralRe: Run this in a real machine. PinmemberRoNaK gOhel5-Dec-14 3:34 
Generalgreat article!! PinmemberRye Salvador5-Dec-13 2:01 
Questioncompile error Pinmemberltg183125-Nov-13 22:59 
AnswerRe: compile error PinmemberAshakiranBhatter26-Nov-13 7:31 
GeneralRe: compile error Pinmemberltg183126-Nov-13 15:53 
GeneralRe: compile error PinmemberAshakiranBhatter27-Nov-13 6:28 
GeneralRe: compile error Pinmemberltg183128-Nov-13 0:05 
GeneralMy vote of 1 PinmemberMember 1032614925-Nov-13 13:09 
GeneralRe: My vote of 1 PinmemberAshakiranBhatter25-Nov-13 13:41 
GeneralRe: My vote of 1 Pinmembercplas26-Nov-13 8:10 
GeneralRe: My vote of 1 PinmemberAshakiranBhatter26-Nov-13 8:33 
GeneralRe: My vote of 1 PinmemberMember 1032614926-Nov-13 9:15 
GeneralRe: My vote of 1 PinmemberAshakiranBhatter26-Nov-13 9:34 
QuestionGood article (+4) PinmemberH.Brydon11-Nov-13 4:13 
GeneralMy vote of 5 PinmemberSteppenwolfe10-Nov-13 11:47 
Questionkernel vs bootloader PinmemberRye Salvador8-Nov-13 2:46 
AnswerRe: kernel vs bootloader PinmemberAshakiranBhatter8-Nov-13 5:05 
GeneralRe: kernel vs bootloader PinmemberRye Salvador9-Nov-13 5:42 
GeneralMy vote of 3 PinmemberAndreas S. Franci Gonçalves30-Oct-13 16:42 
GeneralRe: My vote of 3 PinmemberAshakiranBhatter10-Nov-13 11:09 
GeneralRe: My vote of 3 Pinmembercplas26-Nov-13 8:11 
GeneralRe: My vote of 3 PinmemberAshakiranBhatter26-Nov-13 8:33 
GeneralMy vote of 5 PinmemberPratik Bhuva30-Oct-13 5:39 
QuestionGreat article PinprofessionalCIDev30-Oct-13 4:03 

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