I read this concept from book that when we attemp to write \n to the file using fputs(), fputs() converts the \n to \r\n combination and then if we read the same line back using fgets () the reverse conversion happens means \r\n back convert to \n. I don't get that what is the purpose behind this ?
It is because Windows (and MS-DOS) text files are supposed to have lines ending in \r\n, and portable C programs are supposed to simply use \n because C was originally defined on Unix.
And it's not just fputs and fgets that do it - any I/O function on a text file, even getc and fread, will do the same conversion.
Succinctly, DOS is the reason for this.
Different systems have different conventions for line endings. Unix reckons one character,
C originate on Unix, but to make it easier to migrate code between the systems, the standard I/O package defined that when it was working on text files, the input side would convert a native line ending to the single
However, the mention of text files also meant that there needed to be binary files, where these mappings do not occur.
You might note that most of the internet protocols (HTTP, for example) mandate CRLF (carriage return, line feed, or
(Actually, blaming DOS, as in MS-DOS or PC-DOS, is a little unfair. There were other systems that used the CRLF line end convention before DOS existed, and they may have been more influential on the Internet. However, almost all those ancestral systems are substantially defunct, and Windows is the environment that you'll run into these days where the distinction between binary and text files matters, and where you'll encounter CRLF line endings.)
Note that the C standard has this to say about text files:
ISO/IEC 9899:2011 §7.21.2 Files
That's a lot of things that might or might not happen. Note, in particular, that trailing blanks written to a file might, or might not, appear in the input — according to the standard. That allows the systems that support punched card images or fixed length records to comply with the standard.
Note, too (as pointed out by Giacomo Degli Eposti), that this all means that if you open a file in binary mode that was originally written as a text file, you may very well get a significantly different list of bytes back from the I/O system. You'll see two characters per newline; you might see a Control-Z followed by other characters (possibly null bytes) up to a 'block' boundary that might be a multiple of 256 bytes, etc.