; 0-terminated string manipulation routines. For the Virtual Machine target. %import shared_string_functions string { %option ignore_unused sub length(str st) -> ubyte { ; Returns the number of bytes in the string. ; This value is determined during runtime and counts upto the first terminating 0 byte in the string, ; regardless of the size of the string during compilation time. Don’t confuse this with len and sizeof! ubyte count = 0 while st[count] count++ return count } sub left(str source, ubyte slen, str target) { ; Copies the left side of the source string of the given length to target string. ; It is assumed the target string buffer is large enough to contain the result. ; Also, you have to make sure yourself that length is smaller or equal to the length of the source string. ; Modifies in-place, doesn’t return a value (so can’t be used in an expression). target[slen] = 0 ubyte ix for ix in 0 to slen-1 { target[ix] = source[ix] } } sub right(str source, ubyte slen, str target) { ; Copies the right side of the source string of the given length to target string. ; It is assumed the target string buffer is large enough to contain the result. ; Also, you have to make sure yourself that length is smaller or equal to the length of the source string. ; Modifies in-place, doesn’t return a value (so can’t be used in an expression). ubyte offset = length(source)-slen ubyte ix for ix in 0 to slen-1 { target[ix] = source[ix+offset] } target[ix]=0 } sub slice(str source, ubyte start, ubyte slen, str target) { ; Copies a segment from the source string, starting at the given index, ; and of the given length to target string. ; It is assumed the target string buffer is large enough to contain the result. ; Also, you have to make sure yourself that start and length are within bounds of the strings. ; Modifies in-place, doesn’t return a value (so can’t be used in an expression). ubyte ix for ix in 0 to slen-1 { target[ix] = source[ix+start] } target[ix]=0 } sub find(str st, ubyte character) -> ubyte { ; Locates the first position of the given character in the string, ; returns Carry set if found + index in A, or Carry clear if not found. ubyte ix for ix in 0 to length(st)-1 { if st[ix]==character { sys.set_carry() return ix } } sys.clear_carry() return 0 } sub contains(str st, ubyte character) -> bool { void find(st, character) if_cs return true return false } sub copy(str source, str target) -> ubyte { ; Copy a string to another, overwriting that one. ; Returns the length of the string that was copied. ; Often you don’t have to call this explicitly and can just write string1 = string2 ; but this function is useful if you’re dealing with addresses for instance. %ir {{ loadm.w r65534,string.copy.source loadm.w r65535,string.copy.target syscall 52 (r65534.w, r65535.w): r0.b returnr.b r0 }} } sub append(str target, str suffix) -> ubyte { ; Append the suffix string to the target. (make sure the buffer is large enough!) ; Returns the length of the resulting string. cx16.r0L = length(target) return copy(suffix, target+cx16.r0L) + cx16.r0L } sub compare(str st1, str st2) -> byte { ; Compares two strings for sorting. ; Returns -1 (255), 0 or 1 depending on wether string1 sorts before, equal or after string2. ; Note that you can also directly compare strings and string values with eachother using ; comparison operators ==, < etcetera (it will use strcmp for you under water automatically). %ir {{ loadm.w r65534,string.compare.st1 loadm.w r65535,string.compare.st2 syscall 29 (r65534.w, r65535.w) : r0.b returnr.b r0 }} } sub lower(str st) -> ubyte { ; Lowercases the petscii string in-place. Returns length of the string. ; (for efficiency, non-letter characters > 128 will also not be left intact, ; but regular text doesn't usually contain those characters anyway.) ubyte ix repeat { ubyte char=st[ix] if not char return ix if char >= 'A' and char <= 'Z' st[ix] = char | %00100000 ix++ } } sub upper(str st) -> ubyte { ; Uppercases the petscii string in-place. Returns length of the string. ubyte ix repeat { ubyte char=st[ix] if not char return ix if char >= 97 and char <= 122 st[ix] = char & %11011111 ix++ } } sub lowerchar(ubyte char) -> ubyte { if char >= 'A' and char <= 'Z' char |= %00100000 return char } sub upperchar(ubyte char) -> ubyte { if char >= 'a' and char <= 'z' char &= %11011111 return char } sub startswith(str st, str prefix) -> bool { ubyte prefix_len = length(prefix) ubyte str_len = length(st) if prefix_len > str_len return false cx16.r9L = st[prefix_len] st[prefix_len] = 0 cx16.r9H = compare(st, prefix) as ubyte st[prefix_len] = cx16.r9L return cx16.r9H==0 } sub endswith(str st, str suffix) -> bool { ubyte suffix_len = length(suffix) ubyte str_len = length(st) if suffix_len > str_len return false return compare(st + str_len - suffix_len, suffix) == 0 } sub hash(str st) -> ubyte { ; experimental 8 bit hashing function. ; hash(-1)=179; hash(i) = ROL hash(i-1) XOR string[i] ; (experimental because the quality of the resulting hash value still has to be determined) ubyte hashcode = 179 ubyte ix sys.clear_carry() repeat { if st[ix] { rol(hashcode) hashcode ^= st[ix] ix++ } else return hashcode } } sub isdigit(ubyte character) -> bool { return character>='0' and character<='9' } sub isupper(ubyte character) -> bool { return character>='A' and character<='Z' } sub islower(ubyte character) -> bool { return character>='a' and character<='z' } sub isletter(ubyte character) -> bool { return islower(character) or isupper(character) } sub isspace(ubyte character) -> bool { return character in [32, 13, 9, 10, 141, 160] } sub isprint(ubyte character) -> bool { return character>=32 and character<=127 or character>=160 } }