The only truly portable way to do this involves building a lookup table for the input domain, and manually building the chars based on non-linear-assumptions.
Even for the restricted domain of
['a'..'z','A'..'Z'], assuming 'A'..'Z' is contiguous is not defined by the language standard, and is provably not always the case. For any naysayers that think otherwise, I direct you to ordinal positions of characters in the chart at this link, paying close attention to the dead-zones in the middle of the assumed sequences. If you think "Nobody uses EBCDIC anymore", let me assure you both AS/400 and OS/390 are alive and well (and probably processing your US taxes right now, as the IRS is one of IBM's biggest customers).
In fact, the C standard is pretty explicit about this:
C99-22.214.171.124 In both the source and execution basic character sets, the value of each character after 0 in the above list of decimal digits shall be one greater than the value of the previous.
Nowhere is there even a mention of defined ordering or even implied ordering on any other part of the character sets. In fact,
'0'..'9' has one other unique attribute: they are the only characters guaranteed to be unaffected by locale changes.
So rather than assume a linear continuation exists for characters while thumbing our noses at the suspicious silence of the standard, let us define our own, hard map. I'lll not inline the code here like I normally do; if you're still with me you're genuinely interested in knowing and will likely read and critique the code below. But I will describe in summary how it works:
- Static-declare two alphabets, double in length (A..ZA..Z,a..za..z).
- Declare two arrays (encrypt and decrypt) large enough to hold
- Fully initialize both arrays with values corresponding to their indexes. Ex:
- Fill each location in the encrypt-array that is part of our alphabets from (1) with the proper value corresponding to the shift width Ex.
a['a'] = 'g' for a ROT5.
- Mirror (4) by working backward from the tail of the alphabet applying the opposite shift direction. Ex: `a['g'] = 'a';
You can now use the encryption array as a simple table to translate input text to cipher text:
enc-char = encrypt[ dec-char ];
dec-char = decrypt[ enc-char ];
If you think it seems like a ton of work just to get source-level platform independence, you're absolutely right. But you would be amazed at the #ifdef #endif hell that people try to pass off as "multi-platform". The core goal of platform-independent code is to not only define common source, but define behavior as well. No matter what the platform, the concepts above will work. (and not a #ifdef in sight).
Thanks for taking the time to read this fiasco. Such a seemingly simple problem...
// global tables for encoding. must call init_tables() before using
static char xlat_enc[1 << CHAR_BIT];
static char xlat_dec[1 << CHAR_BIT];
void init_tables(unsigned shift)
// our rotation alphabets
static char ucase = "ABCDEFGHIJKLMNOPQRSTUVWXYZABCDEFGHIJKLMNOPQRSTUVWXYZ";
static char lcase = "abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyz";
// ensure shift is below our maximum shift
shift %= 26;
// prime our table
for (;i<(1 << CHAR_BIT);i++)
xlat_enc[i] = xlat_dec[i] = i;
// apply shift to our xlat tables, both enc and dec.
xlat_enc[ lcase[i] ] = lcase[i+shift];
xlat_enc[ ucase[i] ] = ucase[i+shift];
xlat_dec[ lcase[sizeof(lcase) - i - 1] ] = lcase[sizeof(lcase) - i - 1 - shift];
xlat_dec[ ucase[sizeof(ucase) - i - 1] ] = ucase[sizeof(ucase) - i - 1 - shift];
// main entrypoint
int main(int argc, char *argv)
// using a shift of 13 for our sample
const int shift = 13;
// initialize the tables
// now drop the messsage to the console
char plain = "The quick brown fox jumps over the lazy dog.";
char *p = plain;
for (;*p; fputc(xlat_enc[*p++], stdout));
char cipher = "Gur dhvpx oebja sbk whzcf bire gur ynml qbt.";
p = cipher;
for (;*p; fputc(xlat_dec[*p++], stdout));
Gur dhvpx oebja sbk whzcf bire gur ynml qbt.
The quick brown fox jumps over the lazy dog.