// Copyright (c) Athena Dev Teams - Licensed under GNU GPL
// For more information, see LICENCE in the main folder
#include "../common/cbasetypes.h"
#include "../common/malloc.h"
#include "../common/showmsg.h"
#include "strlib.h"
#include <stdio.h>
#include <stdlib.h>
#include <errno.h>
#define J_MAX_MALLOC_SIZE 65535
// escapes a string in-place (' -> \' , \ -> \\ , % -> _)
char* jstrescape (char* pt)
{
//copy from here
char *ptr;
int i = 0, j = 0;
//copy string to temporary
CREATE(ptr, char, J_MAX_MALLOC_SIZE);
strcpy(ptr,pt);
while (ptr[i] != '\0') {
switch (ptr[i]) {
case '\'':
pt[j++] = '\\';
pt[j++] = ptr[i++];
break;
case '\\':
pt[j++] = '\\';
pt[j++] = ptr[i++];
break;
case '%':
pt[j++] = '_'; i++;
break;
default:
pt[j++] = ptr[i++];
}
}
pt[j++] = '\0';
aFree(ptr);
return pt;
}
// escapes a string into a provided buffer
char* jstrescapecpy (char* pt, const char* spt)
{
//copy from here
//WARNING: Target string pt should be able to hold strlen(spt)*2, as each time
//a escape character is found, the target's final length increases! [Skotlex]
int i =0, j=0;
if (!spt) { //Return an empty string [Skotlex]
pt[0] = '\0';
return &pt[0];
}
while (spt[i] != '\0') {
switch (spt[i]) {
case '\'':
pt[j++] = '\\';
pt[j++] = spt[i++];
break;
case '\\':
pt[j++] = '\\';
pt[j++] = spt[i++];
break;
case '%':
pt[j++] = '_'; i++;
break;
default:
pt[j++] = spt[i++];
}
}
pt[j++] = '\0';
return &pt[0];
}
// escapes exactly 'size' bytes of a string into a provided buffer
int jmemescapecpy (char* pt, const char* spt, int size)
{
//copy from here
int i =0, j=0;
while (i < size) {
switch (spt[i]) {
case '\'':
pt[j++] = '\\';
pt[j++] = spt[i++];
break;
case '\\':
pt[j++] = '\\';
pt[j++] = spt[i++];
break;
case '%':
pt[j++] = '_'; i++;
break;
default:
pt[j++] = spt[i++];
}
}
// copy size is 0 ~ (j-1)
return j;
}
// Function to suppress control characters in a string.
int remove_control_chars(char* str)
{
int i;
int change = 0;
for(i = 0; str[i]; i++) {
if (ISCNTRL(str[i])) {
str[i] = '_';
change = 1;
}
}
return change;
}
// Removes characters identified by ISSPACE from the start and end of the string
// NOTE: make sure the string is not const!!
char* trim(char* str)
{
size_t start;
size_t end;
if( str == NULL )
return str;
// get start position
for( start = 0; str[start] && ISSPACE(str[start]); ++start )
;
// get end position
for( end = strlen(str); start < end && str[end-1] && ISSPACE(str[end-1]); --end )
;
// trim
if( start == end )
*str = '\0';// empty string
else
{// move string with nul terminator
str[end] = '\0';
memmove(str,str+start,end-start+1);
}
return str;
}
// Converts one or more consecutive occurences of the delimiters into a single space
// and removes such occurences from the beginning and end of string
// NOTE: make sure the string is not const!!
char* normalize_name(char* str,const char* delims)
{
char* in = str;
char* out = str;
int put_space = 0;
if( str == NULL || delims == NULL )
return str;
// trim start of string
while( *in && strchr(delims,*in) )
++in;
while( *in )
{
if( put_space )
{// replace trim characters with a single space
*out = ' ';
++out;
}
// copy non trim characters
while( *in && !strchr(delims,*in) )
{
*out = *in;
++out;
++in;
}
// skip trim characters
while( *in && strchr(delims,*in) )
++in;
put_space = 1;
}
*out = '\0';
return str;
}
//stristr: Case insensitive version of strstr, code taken from
//http://www.daniweb.com/code/snippet313.html, Dave Sinkula
//
const char* stristr(const char* haystack, const char* needle)
{
if ( !*needle )
{
return haystack;
}
for ( ; *haystack; ++haystack )
{
if ( TOUPPER(*haystack) == TOUPPER(*needle) )
{
// matched starting char -- loop through remaining chars
const char *h, *n;
for ( h = haystack, n = needle; *h && *n; ++h, ++n )
{
if ( TOUPPER(*h) != TOUPPER(*n) )
{
break;
}
}
if ( !*n ) // matched all of 'needle' to null termination
{
return haystack; // return the start of the match
}
}
}
return 0;
}
#ifdef __WIN32
char* _strtok_r(char *s1, const char *s2, char **lasts)
{
char *ret;
if (s1 == NULL)
s1 = *lasts;
while(*s1 && strchr(s2, *s1))
++s1;
if(*s1 == '\0')
return NULL;
ret = s1;
while(*s1 && !strchr(s2, *s1))
++s1;
if(*s1)
*s1++ = '\0';
*lasts = s1;
return ret;
}
#endif
#if !(defined(WIN32) && defined(_MSC_VER) && _MSC_VER >= 1400) && !defined(HAVE_STRNLEN)
/* Find the length of STRING, but scan at most MAXLEN characters.
If no '\0' terminator is found in that many characters, return MAXLEN. */
size_t strnlen (const char* string, size_t maxlen)
{
const char* end = memchr (string, '\0', maxlen);
return end ? (size_t) (end - string) : maxlen;
}
#endif
#if defined(WIN32) && defined(_MSC_VER) && _MSC_VER <= 1200
uint64 strtoull(const char* str, char** endptr, int base)
{
uint64 result;
int count;
int n;
if( base == 0 )
{
if( str[0] == '0' && (str[1] == 'x' || str[1] == 'X') )
base = 16;
else
if( str[0] == '0' )
base = 8;
else
base = 10;
}
if( base == 8 )
count = sscanf(str, "%I64o%n", &result, &n);
else
if( base == 10 )
count = sscanf(str, "%I64u%n", &result, &n);
else
if( base == 16 )
count = sscanf(str, "%I64x%n", &result, &n);
else
count = 0; // fail
if( count < 1 )
{
errno = EINVAL;
result = 0;
n = 0;
}
if( endptr )
*endptr = (char*)str + n;
return result;
}
#endif
//----------------------------------------------------
// E-mail check: return 0 (not correct) or 1 (valid).
//----------------------------------------------------
int e_mail_check(char* email)
{
char ch;
char* last_arobas;
size_t len = strlen(email);
// athena limits
if (len < 3 || len > 39)
return 0;
// part of RFC limits (official reference of e-mail description)
if (strchr(email, '@') == NULL || email[len-1] == '@')
return 0;
if (email[len-1] == '.')
return 0;
last_arobas = strrchr(email, '@');
if (strstr(last_arobas, "@.") != NULL || strstr(last_arobas, "..") != NULL)
return 0;
for(ch = 1; ch < 32; ch++)
if (strchr(last_arobas, ch) != NULL)
return 0;
if (strchr(last_arobas, ' ') != NULL || strchr(last_arobas, ';') != NULL)
return 0;
// all correct
return 1;
}
//--------------------------------------------------
// Return numerical value of a switch configuration
// on/off, english, fran�ais, deutsch, espa�ol
//--------------------------------------------------
int config_switch(const char* str)
{
if (strcmpi(str, "on") == 0 || strcmpi(str, "yes") == 0 || strcmpi(str, "oui") == 0 || strcmpi(str, "ja") == 0 || strcmpi(str, "si") == 0)
return 1;
if (strcmpi(str, "off") == 0 || strcmpi(str, "no") == 0 || strcmpi(str, "non") == 0 || strcmpi(str, "nein") == 0)
return 0;
return (int)strtol(str, NULL, 0);
}
/// strncpy that always nul-terminates the string
char* safestrncpy(char* dst, const char* src, size_t n)
{
if( n > 0 )
{
char* d = dst;
const char* s = src;
d[--n] = '\0';/* nul-terminate string */
for( ; n > 0; --n )
{
if( (*d++ = *s++) == '\0' )
{/* nul-pad remaining bytes */
while( --n > 0 )
*d++ = '\0';
break;
}
}
}
return dst;
}
/// doesn't crash on null pointer
size_t safestrnlen(const char* string, size_t maxlen)
{
return ( string != NULL ) ? strnlen(string, maxlen) : 0;
}
/// Works like snprintf, but always nul-terminates the buffer.
/// Returns the size of the string (without nul-terminator)
/// or -1 if the buffer is too small.
///
/// @param buf Target buffer
/// @param sz Size of the buffer (including nul-terminator)
/// @param fmt Format string
/// @param ... Format arguments
/// @return The size of the string or -1 if the buffer is too small
int safesnprintf(char* buf, size_t sz, const char* fmt, ...)
{
va_list ap;
int ret;
va_start(ap,fmt);
ret = vsnprintf(buf, sz, fmt, ap);
va_end(ap);
if( ret < 0 || (size_t)ret >= sz )
{// overflow
buf[sz-1] = '\0';// always nul-terminate
return -1;
}
return ret;
}
/// Returns the line of the target position in the string.
/// Lines start at 1.
int strline(const char* str, size_t pos)
{
const char* target;
int line;
if( str == NULL || pos == 0 )
return 1;
target = str+pos;
for( line = 1; ; ++line )
{
str = strchr(str, '\n');
if( str == NULL || target <= str )
break;// found target line
++str;// skip newline
}
return line;
}
/// Produces the hexadecimal representation of the given input.
/// The output buffer must be at least count*2+1 in size.
/// Returns true on success, false on failure.
///
/// @param output Output string
/// @param input Binary input buffer
/// @param count Number of bytes to convert
bool bin2hex(char* output, unsigned char* input, size_t count)
{
char toHex[] = "0123456789abcdef";
size_t i;
for( i = 0; i < count; ++i )
{
*output++ = toHex[(*input & 0xF0) >> 4];
*output++ = toHex[(*input & 0x0F) >> 0];
++input;
}
*output = '\0';
return true;
}
/////////////////////////////////////////////////////////////////////
/// Parses a single field in a delim-separated string.
/// The delimiter after the field is skipped.
///
/// @param sv Parse state
/// @return 1 if a field was parsed, 0 if already done, -1 on error.
int sv_parse_next(struct s_svstate* sv)
{
enum {
START_OF_FIELD,
PARSING_FIELD,
PARSING_C_ESCAPE,
END_OF_FIELD,
TERMINATE,
END
} state;
const char* str;
int len;
enum e_svopt opt;
char delim;
int i;
if( sv == NULL )
return -1;// error
str = sv->str;
len = sv->len;
opt = sv->opt;
delim = sv->delim;
// check opt
if( delim == '\n' && (opt&(SV_TERMINATE_CRLF|SV_TERMINATE_LF)) )
{
ShowError("sv_parse_next: delimiter '\\n' is not compatible with options SV_TERMINATE_LF or SV_TERMINATE_CRLF.\n");
return -1;// error
}
if( delim == '\r' && (opt&(SV_TERMINATE_CRLF|SV_TERMINATE_CR)) )
{
ShowError("sv_parse_next: delimiter '\\r' is not compatible with options SV_TERMINATE_CR or SV_TERMINATE_CRLF.\n");
return -1;// error
}
if( sv->done || str == NULL )
{
sv->done = true;
return 0;// nothing to parse
}
#define IS_END() ( i >= len )
#define IS_DELIM() ( str[i] == delim )
#define IS_TERMINATOR() ( \
((opt&SV_TERMINATE_LF) && str[i] == '\n') || \
((opt&SV_TERMINATE_CR) && str[i] == '\r') || \
((opt&SV_TERMINATE_CRLF) && i+1 < len && str[i] == '\r' && str[i+1] == '\n') )
#define IS_C_ESCAPE() ( (opt&SV_ESCAPE_C) && str[i] == '\\' )
#define SET_FIELD_START() sv->start = i
#define SET_FIELD_END() sv->end = i
i = sv->off;
state = START_OF_FIELD;
while( state != END )
{
switch( state )
{
case START_OF_FIELD:// record start of field and start parsing it
SET_FIELD_START();
state = PARSING_FIELD;
break;
case PARSING_FIELD:// skip field character
if( IS_END() || IS_DELIM() || IS_TERMINATOR() )
state = END_OF_FIELD;
else if( IS_C_ESCAPE() )
state = PARSING_C_ESCAPE;
else
++i;// normal character
break;
case PARSING_C_ESCAPE:// skip escape sequence (validates it too)
{
++i;// '\\'
if( IS_END() )
{
ShowError("sv_parse_next: empty escape sequence\n");
return -1;
}
if( str[i] == 'x' )
{// hex escape
++i;// 'x'
if( IS_END() || !ISXDIGIT(str[i]) )
{
ShowError("sv_parse_next: \\x with no following hex digits\n");
return -1;
}
do{
++i;// hex digit
}while( !IS_END() && ISXDIGIT(str[i]));
}
else if( str[i] == '0' || str[i] == '1' || str[i] == '2' )
{// octal escape
++i;// octal digit
if( !IS_END() && str[i] >= '0' && str[i] <= '7' )
++i;// octal digit
if( !IS_END() && str[i] >= '0' && str[i] <= '7' )
++i;// octal digit
}
else if( strchr(SV_ESCAPE_C_SUPPORTED, str[i]) )
{// supported escape character
++i;
}
else
{
ShowError("sv_parse_next: unknown escape sequence \\%c\n", str[i]);
return -1;
}
state = PARSING_FIELD;
break;
}
case END_OF_FIELD:// record end of field and stop
SET_FIELD_END();
state = END;
if( IS_END() )
;// nothing else
else if( IS_DELIM() )
++i;// delim
else if( IS_TERMINATOR() )
state = TERMINATE;
break;
case TERMINATE:
#if 0
// skip line terminator
if( (opt&SV_TERMINATE_CRLF) && i+1 < len && str[i] == '\r' && str[i+1] == '\n' )
i += 2;// CRLF
else
++i;// CR or LF
#endif
sv->done = true;
state = END;
break;
}
}
if( IS_END() )
sv->done = true;
sv->off = i;
#undef IS_END
#undef IS_DELIM
#undef IS_TERMINATOR
#undef IS_C_ESCAPE
#undef SET_FIELD_START
#undef SET_FIELD_END
return 1;
}
/// Parses a delim-separated string.
/// Starts parsing at startoff and fills the pos array with position pairs.
/// out_pos[0] and out_pos[1] are the start and end of line.
/// Other position pairs are the start and end of fields.
/// Returns the number of fields found or -1 if an error occurs.
///
/// out_pos can be NULL.
/// If a line terminator is found, the end position is placed there.
/// out_pos[2] and out_pos[3] for the first field, out_pos[4] and out_pos[5]
/// for the seconds field and so on.
/// Unfilled positions are set to -1.
///
/// @param str String to parse
/// @param len Length of the string
/// @param startoff Where to start parsing
/// @param delim Field delimiter
/// @param out_pos Array of resulting positions
/// @param npos Size of the pos array
/// @param opt Options that determine the parsing behaviour
/// @return Number of fields found in the string or -1 if an error occured
int sv_parse(const char* str, int len, int startoff, char delim, int* out_pos, int npos, enum e_svopt opt)
{
struct s_svstate sv;
int count;
// initialize
if( out_pos == NULL ) npos = 0;
for( count = 0; count < npos; ++count )
out_pos[count] = -1;
sv.str = str;
sv.len = len;
sv.off = startoff;
sv.opt = opt;
sv.delim = delim;
sv.done = false;
// parse
count = 0;
if( npos > 0 ) out_pos[0] = startoff;
while( !sv.done )
{
++count;
if( sv_parse_next(&sv) <= 0 )
return -1;// error
if( npos > count*2 ) out_pos[count*2] = sv.start;
if( npos > count*2+1 ) out_pos[count*2+1] = sv.end;
}
if( npos > 1 ) out_pos[1] = sv.off;
return count;
}
/// Splits a delim-separated string.
/// WARNING: this function modifies the input string
/// Starts splitting at startoff and fills the out_fields array.
/// out_fields[0] is the start of the next line.
/// Other entries are the start of fields (nul-teminated).
/// Returns the number of fields found or -1 if an error occurs.
///
/// out_fields can be NULL.
/// Fields that don't fit in out_fields are not nul-terminated.
/// Extra entries in out_fields are filled with the end of the last field (empty string).
///
/// @param str String to parse
/// @param len Length of the string
/// @param startoff Where to start parsing
/// @param delim Field delimiter
/// @param out_fields Array of resulting fields
/// @param nfields Size of the field array
/// @param opt Options that determine the parsing behaviour
/// @return Number of fields found in the string or -1 if an error occured
int sv_split(char* str, int len, int startoff, char delim, char** out_fields, int nfields, enum e_svopt opt)
{
int pos[1024];
int i;
int done;
char* end;
int ret = sv_parse(str, len, startoff, delim, pos, ARRAYLENGTH(pos), opt);
if( ret == -1 || out_fields == NULL || nfields <= 0 )
return ret; // nothing to do
// next line
end = str + pos[1];
if( end[0] == '\0' )
{
*out_fields = end;
}
else if( (opt&SV_TERMINATE_LF) && end[0] == '\n' )
{
if( !(opt&SV_KEEP_TERMINATOR) )
end[0] = '\0';
*out_fields = end + 1;
}
else if( (opt&SV_TERMINATE_CRLF) && end[0] == '\r' && end[1] == '\n' )
{
if( !(opt&SV_KEEP_TERMINATOR) )
end[0] = end[1] = '\0';
*out_fields = end + 2;
}
else if( (opt&SV_TERMINATE_CR) && end[0] == '\r' )
{
if( !(opt&SV_KEEP_TERMINATOR) )
end[0] = '\0';
*out_fields = end + 1;
}
else
{
ShowError("sv_split: unknown line delimiter 0x02%x.\n", (unsigned char)end[0]);
return -1;// error
}
++out_fields;
--nfields;
// fields
i = 2;
done = 0;
while( done < ret && nfields > 0 )
{
if( i < ARRAYLENGTH(pos) )
{// split field
*out_fields = str + pos[i];
end = str + pos[i+1];
*end = '\0';
// next field
i += 2;
++done;
++out_fields;
--nfields;
}
else
{// get more fields
sv_parse(str, len, pos[i-1] + 1, delim, pos, ARRAYLENGTH(pos), opt);
i = 2;
}
}
// remaining fields
for( i = 0; i < nfields; ++i )
out_fields[i] = end;
return ret;
}
/// Escapes src to out_dest according to the format of the C compiler.
/// Returns the length of the escaped string.
/// out_dest should be len*4+1 in size.
///
/// @param out_dest Destination buffer
/// @param src Source string
/// @param len Length of the source string
/// @param escapes Extra characters to be escaped
/// @return Length of the escaped string
size_t sv_escape_c(char* out_dest, const char* src, size_t len, const char* escapes)
{
size_t i;
size_t j;
if( out_dest == NULL )
return 0;// nothing to do
if( src == NULL )
{// nothing to escape
*out_dest = 0;
return 0;
}
if( escapes == NULL )
escapes = "";
for( i = 0, j = 0; i < len; ++i )
{
switch( src[i] )
{
case '\0':// octal 0
out_dest[j++] = '\\';
out_dest[j++] = '0';
out_dest[j++] = '0';
out_dest[j++] = '0';
break;
case '\r':// carriage return
out_dest[j++] = '\\';
out_dest[j++] = 'r';
break;
case '\n':// line feed
out_dest[j++] = '\\';
out_dest[j++] = 'n';
break;
case '\\':// escape character
out_dest[j++] = '\\';
out_dest[j++] = '\\';
break;
default:
if( strchr(escapes,src[i]) )
{// escape
out_dest[j++] = '\\';
switch( src[i] )
{
case '\a': out_dest[j++] = 'a'; break;
case '\b': out_dest[j++] = 'b'; break;
case '\t': out_dest[j++] = 't'; break;
case '\v': out_dest[j++] = 'v'; break;
case '\f': out_dest[j++] = 'f'; break;
case '\?': out_dest[j++] = '?'; break;
default:// to octal
out_dest[j++] = '0'+((char)(((unsigned char)src[i]&0700)>>6));
out_dest[j++] = '0'+((char)(((unsigned char)src[i]&0070)>>3));
out_dest[j++] = '0'+((char)(((unsigned char)src[i]&0007) ));
break;
}
}
else
out_dest[j++] = src[i];
break;
}
}
out_dest[j] = 0;
return j;
}
/// Unescapes src to out_dest according to the format of the C compiler.
/// Returns the length of the unescaped string.
/// out_dest should be len+1 in size and can be the same buffer as src.
///
/// @param out_dest Destination buffer
/// @param src Source string
/// @param len Length of the source string
/// @return Length of the escaped string
size_t sv_unescape_c(char* out_dest, const char* src, size_t len)
{
static unsigned char low2hex[256] = {
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,// 0x0?
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,// 0x1?
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,// 0x2?
0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 0, 0, 0, 0, 0, 0,// 0x3?
0, 10, 11, 12, 13, 14, 15, 0, 0, 0, 0, 0, 0, 0, 0, 0,// 0x4?
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,// 0x5?
0, 10, 11, 12, 13, 14, 15, 0, 0, 0, 0, 0, 0, 0, 0, 0,// 0x6?
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,// 0x7?
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,// 0x8?
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,// 0x9?
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,// 0xA?
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,// 0xB?
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,// 0xC?
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,// 0xD?
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,// 0xE?
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 // 0xF?
};
size_t i;
size_t j;
for( i = 0, j = 0; i < len; )
{
if( src[i] == '\\' )
{
++i;// '\\'
if( i >= len )
ShowWarning("sv_unescape_c: empty escape sequence\n");
else if( src[i] == 'x' )
{// hex escape sequence
unsigned char c = 0;
unsigned char inrange = 1;
++i;// 'x'
if( i >= len || !ISXDIGIT(src[i]) )
{
ShowWarning("sv_unescape_c: \\x with no following hex digits\n");
continue;
}
do{
if( c > 0x0F && inrange )
{
ShowWarning("sv_unescape_c: hex escape sequence out of range\n");
inrange = 0;
}
c = (c<<4)|low2hex[(unsigned char)src[i]];// hex digit
++i;
}while( i < len && ISXDIGIT(src[i]) );
out_dest[j++] = (char)c;
}
else if( src[i] == '0' || src[i] == '1' || src[i] == '2' || src[i] == '3' )
{// octal escape sequence (255=0377)
unsigned char c = src[i]-'0';
++i;// '0', '1', '2' or '3'
if( i < len && src[i] >= '0' && src[i] <= '7' )
{
c = (c<<3)|(src[i]-'0');
++i;// octal digit
}
if( i < len && src[i] >= '0' && src[i] <= '7' )
{
c = (c<<3)|(src[i]-'0');
++i;// octal digit
}
out_dest[j++] = (char)c;
}
else
{// other escape sequence
if( strchr(SV_ESCAPE_C_SUPPORTED, src[i]) == NULL )
ShowWarning("sv_unescape_c: unknown escape sequence \\%c\n", src[i]);
switch( src[i] )
{
case 'a': out_dest[j++] = '\a'; break;
case 'b': out_dest[j++] = '\b'; break;
case 't': out_dest[j++] = '\t'; break;
case 'n': out_dest[j++] = '\n'; break;
case 'v': out_dest[j++] = '\v'; break;
case 'f': out_dest[j++] = '\f'; break;
case 'r': out_dest[j++] = '\r'; break;
case '?': out_dest[j++] = '\?'; break;
default: out_dest[j++] = src[i]; break;
}
++i;// escaped character
}
}
else
out_dest[j++] = src[i++];// normal character
}
out_dest[j] = 0;
return j;
}
/// Skips a C escape sequence (starting with '\\').
const char* skip_escaped_c(const char* p)
{
if( p && *p == '\\' )
{
++p;
switch( *p )
{
case 'x':// hexadecimal
++p;
while( ISXDIGIT(*p) )
++p;
break;
case '0':
case '1':
case '2':
case '3':// octal
++p;
if( *p >= '0' && *p <= '7' )
++p;
if( *p >= '0' && *p <= '7' )
++p;
break;
default:
if( *p && strchr(SV_ESCAPE_C_SUPPORTED, *p) )
++p;
}
}
return p;
}
/// Opens and parses a file containing delim-separated columns, feeding them to the specified callback function row by row.
/// Tracks the progress of the operation (current line number, number of successfully processed rows).
/// Returns 'true' if it was able to process the specified file, or 'false' if it could not be read.
///
/// @param directory Directory
/// @param filename File to process
/// @param delim Field delimiter
/// @param mincols Minimum number of columns of a valid row
/// @param maxcols Maximum number of columns of a valid row
/// @param parseproc User-supplied row processing function
/// @return true on success, false if file could not be opened
bool sv_readdb(const char* directory, const char* filename, char delim, int mincols, int maxcols, int maxrows, bool (*parseproc)(char* fields[], int columns, int current))
{
FILE* fp;
int lines = 0;
int entries = 0;
char** fields; // buffer for fields ([0] is reserved)
int columns, fields_length;
char path[1024], line[1024];
char* match;
snprintf(path, sizeof(path), "%s/%s", directory, filename);
// open file
fp = fopen(path, "r");
if( fp == NULL )
{
ShowError("sv_readdb: can't read %s\n", path);
return false;
}
// allocate enough memory for the maximum requested amount of columns plus the reserved one
fields_length = maxcols+1;
fields = aMalloc(fields_length*sizeof(char*));
// process rows one by one
while( fgets(line, sizeof(line), fp) )
{
lines++;
if( ( match = strstr(line, "//") ) != NULL )
{// strip comments
match[0] = 0;
}
//TODO: strip trailing whitespace
if( line[0] == '\0' || line[0] == '\n' || line[0] == '\r')
continue;
columns = sv_split(line, strlen(line), 0, delim, fields, fields_length, (e_svopt)(SV_TERMINATE_LF|SV_TERMINATE_CRLF));
if( columns < mincols )
{
ShowError("sv_readdb: Insufficient columns in line %d of \"%s\" (found %d, need at least %d).\n", lines, path, columns, mincols);
continue; // not enough columns
}
if( columns > maxcols )
{
ShowError("sv_readdb: Too many columns in line %d of \"%s\" (found %d, maximum is %d).\n", lines, path, columns, maxcols );
continue; // too many columns
}
if( entries == maxrows )
{
ShowError("sv_readdb: Reached the maximum allowed number of entries (%d) when parsing file \"%s\".\n", maxrows, path);
break;
}
// parse this row
if( !parseproc(fields+1, columns, entries) )
{
ShowError("sv_readdb: Could not process contents of line %d of \"%s\".\n", lines, path);
continue; // invalid row contents
}
// success!
entries++;
}
aFree(fields);
fclose(fp);
ShowStatus("Done reading '"CL_WHITE"%d"CL_RESET"' entries in '"CL_WHITE"%s"CL_RESET"'.\n", entries, path);
return true;
}
/////////////////////////////////////////////////////////////////////
// StringBuf - dynamic string
//
// @author MouseJstr (original)
/// Allocates a StringBuf
StringBuf* StringBuf_Malloc()
{
StringBuf* self;
CREATE(self, StringBuf, 1);
StringBuf_Init(self);
return self;
}
/// Initializes a previously allocated StringBuf
void StringBuf_Init(StringBuf* self)
{
self->max_ = 1024;
self->ptr_ = self->buf_ = (char*)aMallocA(self->max_ + 1);
}
/// Appends the result of printf to the StringBuf
int StringBuf_Printf(StringBuf* self, const char* fmt, ...)
{
int len;
va_list ap;
va_start(ap, fmt);
len = StringBuf_Vprintf(self, fmt, ap);
va_end(ap);
return len;
}
/// Appends the result of vprintf to the StringBuf
int StringBuf_Vprintf(StringBuf* self, const char* fmt, va_list ap)
{
int n, size, off;
for(;;)
{
va_list apcopy;
/* Try to print in the allocated space. */
size = self->max_ - (self->ptr_ - self->buf_);
va_copy(apcopy, ap);
n = vsnprintf(self->ptr_, size, fmt, apcopy);
va_end(apcopy);
/* If that worked, return the length. */
if( n > -1 && n < size )
{
self->ptr_ += n;
return (int)(self->ptr_ - self->buf_);
}
/* Else try again with more space. */
self->max_ *= 2; // twice the old size
off = (int)(self->ptr_ - self->buf_);
self->buf_ = (char*)aRealloc(self->buf_, self->max_ + 1);
self->ptr_ = self->buf_ + off;
}
}
/// Appends the contents of another StringBuf to the StringBuf
int StringBuf_Append(StringBuf* self, const StringBuf* sbuf)
{
int available = self->max_ - (self->ptr_ - self->buf_);
int needed = (int)(sbuf->ptr_ - sbuf->buf_);
if( needed >= available )
{
int off = (int)(self->ptr_ - self->buf_);
self->max_ += needed;
self->buf_ = (char*)aRealloc(self->buf_, self->max_ + 1);
self->ptr_ = self->buf_ + off;
}
memcpy(self->ptr_, sbuf->buf_, needed);
self->ptr_ += needed;
return (int)(self->ptr_ - self->buf_);
}
// Appends str to the StringBuf
int StringBuf_AppendStr(StringBuf* self, const char* str)
{
int available = self->max_ - (self->ptr_ - self->buf_);
int needed = (int)strlen(str);
if( needed >= available )
{// not enough space, expand the buffer (minimum expansion = 1024)
int off = (int)(self->ptr_ - self->buf_);
self->max_ += max(needed, 1024);
self->buf_ = (char*)aRealloc(self->buf_, self->max_ + 1);
self->ptr_ = self->buf_ + off;
}
memcpy(self->ptr_, str, needed);
self->ptr_ += needed;
return (int)(self->ptr_ - self->buf_);
}
// Returns the length of the data in the Stringbuf
int StringBuf_Length(StringBuf* self)
{
return (int)(self->ptr_ - self->buf_);
}
/// Returns the data in the StringBuf
char* StringBuf_Value(StringBuf* self)
{
*self->ptr_ = '\0';
return self->buf_;
}
/// Clears the contents of the StringBuf
void StringBuf_Clear(StringBuf* self)
{
self->ptr_ = self->buf_;
}
/// Destroys the StringBuf
void StringBuf_Destroy(StringBuf* self)
{
aFree(self->buf_);
self->ptr_ = self->buf_ = 0;
self->max_ = 0;
}
// Frees a StringBuf returned by StringBuf_Malloc
void StringBuf_Free(StringBuf* self)
{
StringBuf_Destroy(self);
aFree(self);
}