Introduction to Computers PDF
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This document provides a basic introduction to computers, explaining the five fundamental operations of any computer system: input, storage, processing, output, and control. It details the function of each component, like input units, storage units, and the central processing unit (CPU).
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MODULE 1 LECTURE NOTE-1 INTRODUCTION TO COMPUTERS Any programming language is implemented on a computer. Right form its inception, to the pres...
MODULE 1 LECTURE NOTE-1 INTRODUCTION TO COMPUTERS Any programming language is implemented on a computer. Right form its inception, to the present day, all computer system (irrespective of their shape & size) perform the following 5 basic operations. It converts the raw input data into information, which is useful to the users. Inputting: It is the process of entering data & instructions to the computer system. Storing: The data & instructions are stored for either initial or additional processing, as & when required. Processing: It requires performing arithmetic or logical operation on the saved data to convert it into useful information. Outputting: It is the process of producing the output data to the end user. Controlling: The above operations have to be directed in a particular sequence to be completed. Based on these 5 operations, we can sketch the block diagram of a computer. Fig 1: Block Diagram of a Computer Input Unit: We need to first enter the data & instruction in the computer system, before any computation begins. This task is accomplished by the input devices. (Eg: keyboard, mouse, scanner, digital camera etc). This device is responsible for linking the system with the external environment. The data accepted is in a human readable form. The input device converts it into a computer readable form. Storage Unit: The data & instruction that are entered have to be stored in the computer. Similarly, the end results & the intermediate results also have to be stored somewhere before being passed to the output unit. The storage unit provides solution to all these issues. This storage unit is designed to save the initial data, the intermediate result & the final result. This storage unit has 2 units: Primary storage & Secondary storage. Primary Storage: The primary storage, also called as the main memory, holds the data when the computer is currently on. As soon as the system is switched off or restarted, the information held in primary storage disappears (i.e. it is volatile in nature). Moreover, the primary storage normally has a limited storage capacity, because it is very expensive as it is made up of semiconductor devices. Secondary Storage: The secondary storage, also called as the auxiliary storage, handles the storage limitation & the volatile nature of the primary memory. It can retain information even when the system is off. It is basically used for holding the program instructions & data on which the computer is not working on currently, but needs to process them later. Central Processing Unit: Together the Control Unit & the Arithmetic Logic Unit are called as the Central Processing Unit (CPU). The CPU is the brain of the computer. Like in humans, the major decisions are taken by the brain itself & other body parts function as directed by the brain. Similarly in a computer system, all the major calculations & comparisons are made inside the CPU. The CPU is responsible for activating & controlling the operation of other units of the computer system. Arithmetic Logic Unit: The actual execution of the instructions (arithmetic or logical operations) takes place over here. The data & instructions stored in the primary storage are transferred as & when required. No processing is done in the primary storage. Intermediate results that are generated in ALU are temporarily transferred back to the primary storage, until needed later. Hence, data may move from the primary storage to ALU & back again to storage, many times, before the processing is done. Control Unit: This unit controls the operations of all parts of the computer but does not carry out any actual data processing.It is responsible for the transfer of data and instructions among other units of the computer.It manages and coordinates all the units of the system.It also communicates with Input/Output devices for transfer of data or results from the storage units. Output Unit: The job of an output unit is just the opposite of an input unit. It accepts the results produced by the computer in coded form. It converts these coded results to human readable form. Finally, it displays the converted results to the outside world with the help of output devices ( Eg :monitors, printers, projectors etc..). So when we talk about a computer, we actually mean 2 things: Hardware- This hardware is responsible for all the physical work of the computer. Software- This software commands the hardware what to do & how to do it. Together, the hardware & software form the computer system. This software is further classified as system software & application software. System Software- System software are a set of programs, responsible for running the computer, controlling various operations of computer systems and management of computer resources. They act as an interface between the hardware of the computer & the application software. E.g.: Operating System Application Software- Application software is a set of programs designed to solve a particular problem for users. It allows the end user to do something besides simply running the hardware. E.g.: Web Browser, Gaming Software, etc. LECTURE NOTE-2 INTRODUCTION TO PROGRAMMING A language that is acceptable to a computer system is called a computer language or programming language and the process of creating a sequence of instructions in such a language is called programming or coding. A program is a set of instructions, written to perform a specific task by the computer. A set of large program is called software. To develop software, one must have knowledge of a programming language. Before moving on to any programming language, it is important to know about the various types of languages used by the computer. Let us first know what the basic requirements of the programmers were & what difficulties they faced while programming in that language. COMPUTER LANGUAGES Languages are a means of communication. Normally people interact with each other through a language. On the same pattern, communication with computers is carried out through a language. This language is understood both by the user and the machine. Just as every language like English, Hindi has its own grammatical rules; every computer language is also bounded by rules known as syntax of that language. The user is bound by that syntax while communicating with the computer system. Computer languages are broadly classified as: Low Level Language: The term low level highlights the fact that it is closer to a language which the machine understands. The low level languages are classified as: o Machine Language numbers) understood directly by the computer. It is machine dependent. It is difficult to learn and even more difficult to write programs. o Assembly Language: This is the language where the machine codes comprising of understanding. It is the first step to improve programming structure. Assembly language programming is simpler and less time consuming than machine level programming, it is easier to locate and correct errors in assembly language than in machine language programs. It is also machine dependent. Programmers must have knowledge of the machine on which the program will run. High Level Language: Low level language requires extensive knowledge of the hardware since it is machine dependent. To overcome this limitation, high level language has been evolved which uses normal English, which is easy to understand to solve any problem. High level languages are computer independent and programming becomes quite easy and simple. Various high level languages are given below: o BASIC (Beginners All Purpose Symbolic Instruction Code): It is widely used, easy to learn general purpose language. Mainly used in microcomputers in earlier days. o COBOL (Common Business Oriented language): A standardized language used for commercial applications. o FORTRAN (Formula Translation): Developed for solving mathematical and scientific problems. One of the most popular languages among scientific community. o C: Structured Programming Language used for all purpose such as scientific application, commercial application, developing games etc. o C++: Popular object oriented programming language, used for general purpose. PROGRAMMING LANGUAGE TRANSLATORS As you know that high level language is machine independent and assembly language though it is machine dependent yet mnemonics that are being used to represent instructions are not directly understandable by the machine. Hence to make the machine understand the instructions provided by both the languages, programming language instructors are used. They transform the instruction prepared by programmers into a form which can be interpreted & executed by the computer. Flowing are the various tools to achieve this purpose: Compiler: The software that reads a program written in high level language and translates it into an equivalent program in machine language is called as compiler. The program written by the programmer in high level language is called source program and the program generated by the compiler after translation is called as object program. Interpreter: it also executes instructions written in a high level language. Both complier & interpreter have the same goal i.e. to convert high level language into binary instructions, but their method of execution is different. The complier converts the entire source code into machine level program, while the interpreter takes 1 statement, translates it, executes it & then again takes the next statement. Assembler: The software that reads a program written in assembly language and translates it into an equivalent program in machine language is called as assembler. Linker: A linker or link editor is a computer program that takes one or more object files generated by a compiler and combines them into a single executable file, library file, or another object file. LECTURE NOTE -3 INTRODUCTION TO C Brief History of C The C programming language is a structure oriented programming language, developed at Bell Laboratories in 1972 by Dennis Ritchie. (Basic Combined Programming Language BCPL) C language was invented for implementing UNIX operating system. In 1983, the American National Standards Institute (ANSI) established a committee to provide a modern, comprehensive definition of C. The resulting definition, the ANSI Taxonomy of C Language WHY IS C POPULAR It is reliable, simple and easy to use. C is a small, block-structured programming language. C is a portable language, which means that C programs written on one system can be run on other systems with little or no modification. C has one of the largest assortments of operators, such as those used for calculations and data comparisons. Although the programmer has more freedom with data storage, the languages do not check data type accuracy for the programmer. WHY TO STUDY C By the early 1980s, C was already a dominant language in the minicomputer world of Unix systems. Since then, it has spread to personal computers (microcomputers) and to mainframes. Many software houses use C as the preferred language for producing word processing programs, spreadsheets, compilers, and other products. C is an extremely flexible language particularly if it is to be used to write operating systems. Unlike most other languages that have only four or five levels of precedence, C has 15. CHARECTERESTICS OF A C PROGRAM Middle level language. High Level Middle Level Low Level High level languages Low level languages provide almost everything provide all the built-in functions provides nothing that the programmer might found in high level languages, other than access to need to do as already built but provides all building blocks the machines basic into the language that we need to produce the result instruction set we want Examples: C, C++ Assembler Java, Python Small size has only 32 keywords Extensive use of function calls- enables the end user to add their own functions to the C library. Supports loose typing a character can be treated as an integer & vice versa. Structured language Structure oriented Object oriented Non structure In this type of language, large In this type of language, There is no specific programs are divided into small programs are divided into structure for programming programs called functions objects this language Prime focus is on functions and Prime focus is in the data that is N/A procedures that operate on the being operated and not on the data functions or procedures Data moves freely around the Data is hidden and cannot be N/A systems from one function to accessed by external functions another Program structure follows N/A Examples: C++, JAVA and C# (C sharp) BASIC, COBOL, C, Pascal, ALGOL and Modula-2 FORTRAN Low level (Bit Wise) programming readily available Pointer implementation - extensive use of pointers for memory, array, structures and functions. It has high-level constructs. It can handle low-level activities. It produces efficient programs. It can be compiled on a variety of computers. USES The C programming language is used for developing system applications that forms a major portion of operating systems such as Windows, UNIX and Linux. Below are some examples of C being used: Database systems Graphics packages Word processors Spreadsheets Operating system development Compilers and Assemblers Network drivers Interpreters STRUCTURE OF A C PROGRAM The structure of a C program is a protocol (rules) to the programmer, which he has to follow while writing a C program. The general basic structure of C program is shown in the figure below. Based on this structure, we can sketch a C program. Example: #include void main(void) { int number; printf( "Please enter a number: " ); scanf( "%d", &number ); printf( "You entered %d", number ); return 0;} Stepwise explanation: #include The part of the compiler which actually gets your program from the source file is called the preprocessor. #include #include is a pre-processor directive. It is not really part of our program, but instead it is an instruction to the compiler to make it do something. It tells the C compiler to include the contents of a file (in this case the system file called stdio.h). The compiler knows it is a system file, and therefore must be looked for in a special place, by the fact that the filename is enclosed in characters stdio.h is the name of the standard library definition file for all STanDard Input and Output functions. Your program will almost certainly want to send information to the screen and read things from the keyboard, and stdio.h is the name of the file in which the functions that we want to use are defined. The function we want to use is called printf. The actual code of printf will be tied in later by the linker. The ".h" portion of the filename is the language extension, which denotes an include file. void This literally means that this means nothing. In this case, it is referring to the function whose name follows. Void tells to C compiler that a given entity has no meaning, and produces no error. main In this particular example, the only function in the program is called main. A C program is typically made up of large number of functions. Each of these is given a name by the programmer and they refer to each other as the program runs. C regards the name main as a special case and will run this function first i.e. the program execution starts from main. (void) This is a pair of brackets enclosing the keyword void. It tells the compiler that the function main has no parameters. A parameter to a function gives the function something to work on. { (Brace) This is a brace (or curly bracket). As the name implies, braces come in packs of two - for every open brace there must be a matching close one. Braces allow us to group pieces of program together, often called a block. A block can contain the declaration of variable used within it, followed by a sequence of program statements. In this case the braces enclose the working parts of the function main. ; (semicolon) The semicolon marks the end of the list of variable names, and also the end of that declaration statement. All statements in C programs are separated by ";" (semicolon) characters. The ";" character is actually very important. It tells the compiler where a given statement ends. If the compiler does not find one of these characters where it expects to see one, then it will produce an error. scanf In other programming languages, the printing and reading functions are a part of the language. In C this is not the case; instead they are defined as standard functions which are part of the language specification, but are not a part of the language itself. The standard input/output library contains a number of functions for formatted data transfer; the two we are going to use are scanf (scan formatted) and printf (print formatted). printf The printf function is the opposite of scanf. It takes text and values from within the program and sends it out onto the screen. Just like scanf, it is common to all versions of C and just like scanf, it is described in the system file stdio.h. The first parameter to a printf is the format string, which contains text, value descriptions and formatting instructions. FILES USED IN A C PROGRAM Source File- This file contains the source code of the program. The file extension of any c file is.c. The file contains C source code that defines the main function & maybe other functions. Header File- A header file is a file with extension.h which contains the C function declarations and macro definitions and to be shared between several source files. Object File- An object file is a file containing object code, with an extension.o, meaning relocatable format machine code that is usually not directly executable. Object files are produced by an assembler, compiler, or other language translator, and used as input to the linker, which in turn typically generates an executable or library by combining parts of object files. Executable File- The binary executable file is generated by the linker. The linker links the various object files to produce a binary file that can be directly executed. COMPLIATION & EXECUTION OF A C PROGRAM LECTURE NOTE -4 ELEMENTS OF C Every language has some basic elements & grammatical rules. Before starting with programming, we should be acquainted with the basic elements that build the language. Character Set Communicating with a computer involves speaking the language the computer understands. In C, various characters have been given to communicate. Character set in C consists of; Types Character Set Lower case a-z Upper case A-Z Digits 0-9 Special Character !@#$%^&* White space Tab or new lines or space Keywords Keywords are the words whose meaning has already been explained to the C compiler. The keywords cannot be used as variable names because if we do so we are trying to assign a new meaning to the keyword, which is not allowed by the computer. There are only 32 keywords available in C. Below figure gives a list of these keywords for your ready reference. Identifier In the programming language C, an identifier is a combination of alphanumeric characters, the first being a letter of the alphabet or an underline, and the remaining being any letter of the alphabet, any numeric digit, or the underline. Two rules must be kept in mind when naming identifiers. 1. The case of alphabetic characters is significant. Using "INDEX" for a variable is not the same as using "index" and neither of them is the same as using "InDeX" for a variable. All three refer to different variables. 2. As C is defined, up to 32 significant characters can be used and will be considered significant by most compilers. If more than 32 are used, they will be ignored by the compiler. Data Type In the C programming language, data types refer to a domain of allowed values & the operations that can be performed on those values. The type of a variable determines how much space it occupies in storage and how the bit pattern stored is interpreted. There are 4 fundamental data types in C, which are- char, int, float &, double. Char is used to store any single character; int is used to store any integer value, float is used to store any single precision floating point number & double is used to store any double precision floating point number. We can use 2 qualifiers with these basic types to get more types. There are 2 types of qualifiers- Sign qualifier- signed & unsigned Size qualifier- short & long The data types in C can be classified as follows: Type Storage size Value range char 1 byte -128 to 127 unsigned char 1 byte 0 to 255 int 2 or 4 bytes -32,768 to 32,767 or -2,147,483,648 to 2,147,483,647 unsigned int 2 or 4 bytes 0 to 65,535 or 0 to 4,294,967,295 short 2 bytes -32,768 to 32,767 unsigned short 2 bytes 0 to 65,535 long 4 bytes -2,147,483,648 to 2,147,483,647 unsigned long 4 bytes 0 to 4,294,967,295 Type Storage size Value range Precision float 4 bytes 1.2E-38 to 3.4E+38 6 decimal places double 8 bytes 2.3E-308 to 1.7E+308 15 decimal places long double 10 bytes 3.4E-4932 to 1.1E+4932 19 decimal places Constants C constants can be divided into two major categories: Primary Constants Secondary Constants Here our only focus is on primary constant. For constructing these different types of constants certain rules have been laid down. Rules for Constructing Integer Constants: An integer constant must have at least one digit. a) It must not have a decimal point. b) It can be either positive or negative. c) If no sign precedes an integer constant it is assumed to be positive. d) No commas or blanks are allowed within an integer constant. e) The allowable range for integer constants is -32768to 32767. Ex.: 426, +782,-8000, -7605 Rules for Constructing Real Constants: Real constants are often called Floating Point constants. The real constants could be written in two forms Fractional form and Exponential form. Rules for constructing real constants expressed in fractional form: a) A real constant must have at least one digit. b) It must have a decimal point. c) It could be either positive or negative. d) Default sign is positive. e) No commas or blanks are allowed within a real constant. Ex. +325.34, 426.0, -32.76, -48.5792 Rules for constructing real constants expressed in exponential form: a) The mantissa part and the exponential part should be separated by a letter e. b) The mantissa part may have a positive or negative sign. c) Default sign of mantissa part is positive. d) The exponent must have at least one digit, which must be a positive or negative integer. Default sign is positive. e) Range of real constants expressed in exponential form is -3.4e38 to 3.4e38. Ex. +3.2e-5, 4.1e8, -0.2e+3, -3.2e-5 Rules for Constructing Character Constants: a) A character constant is a single alphabet, a single digit or a single special symbol enclosed within single inverted commas. b) The maximum length of a character constant can be 1 character. LECTURE NOTE-5 VARIABLES Variables are names that are used to store values. It can take different values but one at a time. A data type is associated with each variable & it decides what values the variable can take. When you decide your program needs another variable, you simply declare (or define) a new variable and C makes sure you get it. You declare all C variables at the top of whatever blocks of code need them. Variable declaration requires that you inform C of the variable's name and data type. Syntax datatype variablename; Eg: int page_no; char grade; float salary; long y; Declaring Variables: There are two places where you can declare a variable: After the opening brace of a block of code (usually at the top of a function) Before a function name (such as before main() in the program) Consider various examples: Suppose you had to keep track of a person's first, middle, and last initials. Because an initial is obviously a character, it would be prudent to declare three character variables to hold the three initials. In C, you could do that with the following statement: 1. main() { char first, middle, last; // Rest of program follows } 2. main() { char first; char middle; char last; // Rest of program follows } Initialization of Variables When a variable is declared, it contains undefined value commonly known as garbage value. If we want we can assign some initial value to the variables during the declaration itself. This is called initialization of the variable. Eg- int pageno=10; float salary= 20000.50; Expressions An expression consists of a combination of operators, operands, variables & function calls. An expression can be arithmetic, logical or relational. Here are some expressions: a+b arithmetic operation a>b- relational operation a == b - logical operation func (a,b) function call 4+21 a*(b + c/d)/20 q = 5*2 x = ++q % 3 q>3 As you can see, the operands can be constants, variables, or combinations of the two. Some expressions are combinations of smaller expressions, called subexpressions. For example, c/d is a subexpression of the sixth example. An important property of C is that every C expression has a value. To find the value, you perform the operations in the order dictated by operator precedence. Statements Statements are the primary building blocks of a program. A program is a series of statements with some necessary punctuation. A statement is a complete instruction to the computer. In C, statements are indicated by a semicolon at the end. Therefore legs = 4 is just an expression (which could be part of a larger expression), but legs = 4; is a statement. What makes a complete instruction? First, C considers any expression to be a statement if you append a semicolon. (These are called expression statements.) Therefore, C won't object to lines such as the following: 8; 3 + 4; However, these statements do nothing for your program and can't really be considered sensible statements. More typically, statements change values and call functions: x = 25; ++x; y = sqrt(x); Although a statement (or, at least, a sensible statement) is a complete instruction, not all complete instructions are statements. Consider the following statement: x = 6 + (y = 5); In it, the subexpression y = 5 is a complete instruction, but it is only part of the statement. Because a complete instruction is not necessarily a statement, a semicolon is needed to identify instructions that truly are statements. Compound Statements (Blocks) A compound statement is two or more statements grouped together by enclosing them in braces; it is also called a block. The following while statement contains an example: while (years < 100) { wisdom = wisdom * 1.05; printf("%d %d\n", years, wisdom); years = years + 1; } If any variable is declared inside the block then it can be declared only at the beginning of the block. The variables that are declared inside a block can be used only within the block. LECTURE NOTE -6 INPUT-OUTPUT IN C When we are saying Input that means we feed some data into program. This can be given in the form of file or from command line. C programming language provides a set of built-in functions to read given input and feed it to the program as per requirement. When we are saying Output that means to display some data on screen, printer or in any file. C programming language provides a set of built-in functions to output the data on the computer screen. Functions printf() and scanf() are the most commonly used to display out and take input respectively. Let us consider an example: #include //This is needed to run printf() function. int main() { printf("C Programming"); //displays the content inside quotation return 0; } Output: C Programming Explanation: Every program starts from main() function. printf() is a library function to display output which only works if #includeis included at the beginning. Here, stdio.h is a header file (standard input output header file) and #include is command to paste the code from the header file when necessary. When compiler encounters printf()function and doesn't find stdio.h header file, compiler shows error. return 0; indicates the successful execution of the program. Input- Output of integers in C #include int main() { int c=5; printf("Number=%d",c); return 0; } Output Number=5 Inside quotation of printf() there, is a conversion format string "%d" (for integer). If this conversion format string matches with remaining argument, i.e, c in this case, value of c is displayed. #include int main() { int c; printf("Enter a number\n"); scanf("%d",&c); printf("Number=%d",c); return 0; } Output Enter a number 4 Number=4 The scanf() function is used to take input from user. In this program, the user is asked an input and value is stored in variable c. Note the '&' sign before c. &c denotes the address of c and value is stored in that address. Input- Output of floats in C #include int main() { float a; printf("Enter value: "); scanf("%f",&a); printf("Value=%f",a); //%f is used for floats instead of %d return 0; } Output Enter value: 23.45 Value=23.450000 Conversion format string "%f" is used for floats to take input and to display floating value of a variable. Input - Output of characters and ASCII code #include int main() { char var1; printf("Enter character: "); scanf("%c",&var1); printf("You entered %c.",var1); return 0; } Output Enter character: g You entered g. Conversion format string "%c" is used in case of characters. ASCII code When character is typed in the above program, the character itself is not recorded a numeric value (ASCII value) is stored. And when we displayed that value by using "%c", that character is displayed. #include int main() { char var1; printf("Enter character: "); scanf("%c",&var1); printf("You entered %c.\n",var1); printf("ASCII value of %d",var1); return 0; } Output: Enter character: g 103 When, 'g' is entered, ASCII value 103 is stored instead of g. You can display character if you know ASCII code only. This is shown by following example. #include int main() { int var1=69; printf("Character of ASCII value 69: %c",var1); return 0; } Output Character of ASCII value 69: E The ASCII value of 'A' is 65, 'B' is 66 and so on to 'Z' is 90. Similarly ASCII value of 'a' is 97, 'b' is 98 and so on to 'z' is 122. LECTURE NOTE-7 FORMATTED INPUT-OUTPUT Data can be entered & displayed in a particular format. Through format specifications, better presentation of results can be obtained. Variations in Output for integer & floats: #include int main() { printf("Case 1:%6d\n",9876); printf("Case 2:%3d\n",9876); printf("Case 3:%.2f\n",987.6543); printf("Case 4:%.f\n",987.6543); printf("Case 5:%e\n",987.6543); return 0; } Output Case 1: 9876 Case 2:9876 Case 3:987.65 Case 4:988 Case 5:9.876543e+002 Variations in Input for integer and floats: #include int main() { int a,b; float c,d; printf("Enter two intgers: "); scanf("%d%d",&a,&b); printf("Enter intger and floating point numbers: "); scanf("%d%f",&a,&c); return 0; } Similarly, any number of inputs can be taken at once from user. EXERCISE: 1. To print out a and b given below, which of the following printf() statement will you use? #include float a=3.14; double b=3.14; A. printf("%f %lf", a, b); B. printf("%Lf %f", a, b); C. printf("%Lf %Lf", a, b); D. printf("%f %Lf", a, b); 2. To scan a and b given below, which of the following scanf() statement will you use? #include float a; double b; A. scanf("%f %f", &a, &b); B. scanf("%Lf %Lf", &a, &b); C. scanf("%f %Lf", &a, &b); D. scanf("%f %lf", &a, &b); 3. For a typical program, the input is taken using. A. scanf B. Files C. Command-line D. None of the mentioned 4. What is the output of this C code? #include int main() { int i = 10, j = 2; printf("%d\n", printf("%d %d ", i, j)); } A. Compile time error B. 10 2 4 C. 10 2 2 D. 10 2 5 5. What is the output of this C code? #include int main() { int i = 10, j = 3; printf("%d %d %d", i, j); } A. Compile time error B. 10 3 C. 10 3 some garbage value D. Undefined behavior 6. What is the output of this C code? #include int main() { int i = 10, j = 3, k = 3; printf("%d %d ", i, j, k); } A. Compile time error B. 10 3 3 C. 10 3 D. 10 3 somegarbage value 7. The syntax to print a % using printf statement can be done by. A. % B. % C. D. %% 8. What is the output of this C code? #include int main() { int n; scanf("%d", n); printf("%d\n", n); return 0; } A. Compilation error B. Undefined behavior C. Whatever user types D. Depends on the standard 9. What is the output of this C code? #include int main() { short int i; scanf("%hd", &i); printf("%hd", i); return 0; } A. Compilation error B. Undefined behavior C. Whatever user types D. None of the mentioned 10. In a call to printf() function the format specifier %b can be used to print binary equivalent of an integer. A. True B. False 11. Point out the error in the program? #include int main() { char ch; int i; scanf("%c", &i); scanf("%d", &ch); printf("%c %d", ch, i); return 0; } A. Error: suspicious char to in conversion in scanf() B. Error: we may not get input for second scanf() statement C. No error D. None of above 12. Which of the following is NOT a delimiter for an input in scanf? A. Enter B. Space C. Tab D. None of the mentioned