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In versions of Mac OS up to version 9, the standard representation for text files used an ASCII CR (carriage return) character, value decimal 13, to mark the end of a line.

Mac OS 10, unlike earlier releases, is UNIX-like, and uses the ASCII LF (line feed) character, value decimal 10, to mark the end of a line.

The question is, what are the values of the character constants '\n' and '\r' in C and C++ compilers for Mac OS releases prior to OS X?

There are (at least) two possible approaches that could have been taken:

  1. Treat '\n' as the ASCII LF character, and convert it to and from CR on output to and input from text streams (similar to the conversion between LF and CR-LF on Windows systems); or
  2. Treat '\n' as the ASCII CR character, which requires no conversion on input or output.

There would be some potential problems with the second approach. One is that code that assumes '\n' is LF could fail. (Such code is inherently non-portable anyway.) The other is that there still needs to be a distinct value for '\r', and on an ASCII-based system CR is the only sensible value. And the C standard doesn't permit '\n' == '\r' (thanks to mafso for finding the citation, 5.2.2 paragraph 3), so some other value would have to be used for '\r'.

What is the output of this C program when compiled and executed under Mac OS N, for N less than 10?

#include <stdio.h>
int main(void) {
    printf("'\\n' = %d\n", '\n');
    printf("'\\r' = %d\n", '\r');
    if ('\n' == '\r') {
        printf("Hmm, this could be a problem\n");

The question applies to both C and C++. I presume the answer would be the same for both.

The answer could also vary from one C compiler to another -- but I would hope that compiler implementers would have maintained consistency with each other.

To be clear, I am not asking what representation old releases of Mac OS used to represent end-of-line in text files. My question is specifically and only about the values of the constants '\n' and '\r' in C or C++ source code. I'm aware that printing '\n' (whatever its value is) to a text stream causes it to be converted to the system's end-of-line representation (in this case, ASCII CR); that behavior is required by the C standard.

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added mac-classic tag... –  Grady Player Jul 31 at 18:09
Booting up my old iMac now... I'll have an answer soon. (Mac OS 8.6) –  Mankarse Jul 31 at 18:19
Classic Mac used \r as the line separator in text files. Since the C I/O library is responsible for transforming between filesystem and in-memory representation, I'd guess \ns were serialized as \r. –  The Paramagnetic Croissant Jul 31 at 18:23
To address how standard conforming '\n' = '\r' would be: Seems unchanged since C89… C11 5.2.2 p3: “Each of these escape sequences shall produce a unique implementation-defined value […]”. So, no, it's not conforming. But what about a character set using 0xd for '\n' and 0xa for '\r'? –  mafso Jul 31 at 18:23
@HotLicks The way I remember it, old macs used '\r' precisely in the same way as UNIX systems use '\n'. There was never a DOS-like combination in use. Microsoft users always annoyed us with that extra character - the mac users with the line-feed, the unix users with the carriage-return... –  cmaster Jul 31 at 19:01

5 Answers 5

up vote 39 down vote accepted

The values of the character constants \r and \n was the exact same in Classic Mac OS environments as it was everywhere else: \r was CR was ASCII 13 (0x0d); \n was LF was ASCII 10 (0x0a). The only thing that was different on Classic Mac OS was that \r was used as the "standard" line ending in text editors, just like \n is used on UNIX systems, or \r\n on DOS and Windows systems.

Here's a screenshot of a simple test program running in Metrowerks CodeWarrior on Mac OS 9, for instance:

Example program running in CodeWarrior

Keep in mind that Classic Mac OS systems didn't have a system-wide standard C library! Functions like printf() were only present as part of compiler-specific libraries like SIOUX for CodeWarrior, which implemented C standard I/O by writing output to a window with a text field in it. As such, some implementations of standard file I/O may have performed some automatic translation between \r and \n, which may be what you're thinking of. (Many Windows systems do similar things for \r\n if you don't pass the "b" flag to fopen(), for instance.) There was certainly nothing like that in the Mac OS Toolbox, though.

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Do you have a reference for this? BTW, any conforming hosted C implementation must include the full standard library, including printf; such an implementation needn't be provided by the OS. –  Keith Thompson Jul 31 at 19:12
Does the mean stdout (in text mode) emitted 13 on both fputc('\n') [translated due to text mode] and fputc('\r')? –  chux Jul 31 at 19:14
@duskwuff: But stdio can open files (fopen) and which bytes are written there is clearly testable. –  R.. Jul 31 at 20:10
This answer is correct. There was also, however, a variation of the standard library available that interpreted files opened in text mode. That is, if the file contained a \r (13) you'd get a \n (10) when you read it in text mode. On output, you'd write a \r (13) and it would actually be written to disk as a \n (10). –  Steven Fisher Jul 31 at 23:46
@LưuVĩnhPhúc: well there was Apple's MPW which was a wonderful environment for developers - you could use it like a shell (or terminal), but every "session" was also an editable text document - I miss it. –  Paul R Aug 1 at 5:43

I've done a search and found this page with an old discussion where especially the following can be found:

The Metrowerks MacOS implementation goes a step further by reversing the significance of CR and LF with regard to the '\r' and '\n' escapes in i/o involving a file, but not in any other context. This means that if you open a FILE or fstream in text mode, every '\r' will be output there as an LF as well as every '\n' being output as CR, and the same is true of input - the escape-to-ASCII-binary correspondences are reversed. They are not reversed however in memory, e.g. with sprintf() to a buffer or with a std::stringstream. I find this confusing and, if not non-standard, at least worse than other implementations.

It turns out there is a workaround with MSL - if you open the file in binary mode then '\n' always == LF and '\r' always == CR. This is what I wanted but in getting this information I also got a lot of justification from folks over there that this was the "standard" way to get what I wanted, when I feel like this is more like a workaround for a bug in their implementation. After all, CR and LF are 7-bit ASCII values and I'd expect to be able to use them in a standard way with a file opened in text mode.

(An answer makes clear that this is indeed not a violation of the standard.)

So obviously there was at least one implementation which used \n and \r with the usual ASCII values, but translated them in (non-binary) file output (by just exchanging them).

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Assuming that '\n' == 10 (ASCII LF), writing '\n' to a text stream would have to translate it to CR, since that's the system's end-of-line marker. Additionally translating '\r' to LF makes some sense, I suppose, and opening a file in binary mode would inhibit the translation. (This is all standard C stuff). So under Metroworks, the output of the program in my question would be '\n' = 10 \r = 13. As far as my question is concerned, that's consistent with duskwuff's answer. –  Keith Thompson Jul 31 at 22:28
@KeithThompson The compiler I used to illustrate my answer was Metrowerks CodeWarrior! –  duskwuff Jul 31 at 22:59

C-language specification:

2 Alphabetic escape sequences representing nongraphic characters in the execution character set are intended to produce actions on display devices as follows:
\n (new line) Moves the active position to the initial position of the next line.
\r (carriage return) Moves the active position to the initial position of the current line.

so \n represents the appropriate char in that character encoding... in ASCII is the LF char

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I don't believe this answers the question. That section also describes the intended behavior of \f and \v; few systems actually behave as described. –  Keith Thompson Jul 31 at 18:23
@KeithThompson I am looking for a document that supports a swap of char values... by the compilers... I believe that they worked this way, I have some old Classic programs that seem to enforce this idea, but I can't run them right now. –  Grady Player Jul 31 at 18:32
@GradyPlayer: if you have some executable files from that period you could examine your strings with a hex viewer. I'm pretty sure a modern one won't silently translate \r back to \n again ;-) –  Jongware Jul 31 at 19:56
I think this does answer the question... We didn't really run portable C programs on the Mac, they were originally written in Pascal and then later C/C++, but we didn't even have a console... so the concept of a newline was basically just in the native controls and in text files, and I remember every mac program reading \n, \r, and \r\n as a newline... where would printf even print? –  Grady Player Jul 31 at 21:05
@GradyPlayer: The question was about the actual values of the '\n' and '\r' character constants, not about how I/O behaves. duskwuff has been able to compile and run the portable C program from my question and produce a screenshot. –  Keith Thompson Jul 31 at 22:19

I don't have an old Mac compiler to check if they follow this, but the numeric value of '\n' should be the same as the ASCII new line character (given that those compilers used ASCII compatible encoding as the execution encoding, which I believe they did). '\r' should have the same numeric value as the ASCII carriage return.

The library or OS functions that handle writing text mode files is responsible for converting the numeric value of '\n' to whatever the OS uses to terminate lines. The numeric values of these characters at runtime are determined entirely by the execution character set.

Thus, since we're still ASCII compatible execution encodings the numeric values should be the same as with classic Mac compilers.

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ASCII does not imply that the LF character is a "newline" character; in fact ASCII has no newline character. A conforming C implementation for old Mac OS could have '\n' == 13 && '\r' == 10 (with no conversion needed on input or output) or it could have '\n' == 10 && '\r' == 13 (and convert LF to CR on text output and CR to LF on text input. The C and ASCII standards by themselves do not answer my question, which is about which of the two (or more) valid choices was made by the authors of C and C++ compilers for classic Mac OS. –  Keith Thompson Jul 31 at 18:43
That would be a conforming implementation, but it would mean the encoding wasn't ascii. The ascii character doesn't need to be named 'newline' to mean the same thing. The question boils down entirely to 'what is the execution encoding used by classic Mac computers.' –  bames53 Jul 31 at 18:47
How so? What in the ASCII standard implies that LF is the correct character to use for newline? –  Keith Thompson Jul 31 at 18:49
Well, I'm sure I could find a rational, but I can't find a copy of ANSI Document X3.4-1986 (R1997). 'line feed' certainly causes printing on the current line to end. –  bames53 Jul 31 at 19:23
And how closely do existing C implementations follow the ASCII standard? Printing a formfeed or vertical tab to a terminal (say, an xterm window) typically does nothing, for example. I don't think we an use the requirements of the ASCII standard to infer how C compilers implement the '\n' character constant. –  Keith Thompson Jul 31 at 19:26

On older Mac compilers, the roles of \r and \n where reversed: We had '\n' == 13 and '\r' == 10, while today '\n' == 10 and '\r' == 13. Great fun during the transition phase. Write a '\n' to a file with an old compiler, read the file with a new compiler, and get a '\r' (of course, both times you actually had a number 13).

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I think you have that backwards; '\n' == 10 and '\r' == 13 would be the modern version. –  Keith Thompson Jul 31 at 18:31
The problem of reading and writing to the file would also occur, if I/O functions did the conversions (as in Windows with \n to \r\n). Just to be sure: Does '\n' == 13 evaluate to 1 on such a system? –  mafso Jul 31 at 18:35
This is not true. \r is always CR is ASCII 13; \n is always LF is ASCII 10. Classic Mac OS just used \r as the standard line ending instead of \n, just like DOS/Windows use the \r\n sequence. –  duskwuff Jul 31 at 19:01
@duskwuff: But we have an assertion that under Classic Mac OS, '\n' == 13. I think we need to see the actual output of the program in my question to settle this. –  Keith Thompson Jul 31 at 19:14
@duskwuff has provided screenshots indicating that '\n' == 10 and '\r == 13; presumably '\n' would be translated to CR on output. Your answer seems to imply that the values of the '\n' and '\r' literals were reversed, which would be inconsistent with the evidence of the screenshots. Could it be that different C compiles behaved differently? –  Keith Thompson Jul 31 at 20:00

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