/* Weather Protocol plugin for Miranda IM Copyright (c) 2012 Miranda NG Team Copyright (c) 2005-2011 Boris Krasnovskiy All Rights Reserved Copyright (c) 2002-2005 Calvin Che This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; version 2 of the License. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ /* This file contain the source related unit conversion, icon assignment, string conversions, display text parsing, etc */ #include "weather.h" //============ SOME HELPER FUNCTIONS ============ // see if a string is a number // s = the string to be determined // return value = true if the string is a number, false if it isn't BOOL is_number(TCHAR *s) { BOOL tag = FALSE; // looking character by character // for a number: numerous spaces in front, then optional +/-, then the number // don't care anything that comes after it while(*s != '\0') { if (*s >= '0' && *s <= '9') return TRUE; else if (*s == ' '); else if (*s != '+' && *s != '-') return FALSE; else if ((*s == '+' || *s == '-') && !tag) tag = TRUE; else return FALSE; s++; } return FALSE; } static void numToStr(double num, TCHAR* str) { int i = (int)(num * (opt.NoFrac ? 10 : 100)); int u = abs(i); int r = u % 10; int w = u / 10 + (r >= 5); if (opt.NoFrac) r = 0; else { r = w % 10; w /= 10; } if (i < 0 && (w || r)) *(str++) = '-'; if (r) wsprintf(str, _T("%i.%i"), w, r); else wsprintf(str, _T("%i"), w); } //============ UNIT CONVERSIONS ============ // temperature conversion // tempchar = the string containing the temperature value // unit = the unit for temperature // return value = the converted temperature with degree sign and unit; if fails, return N/A void GetTemp(TCHAR *tempchar, TCHAR *unit, TCHAR* str) { // unit can be C, F double temp; TCHAR tstr[20]; TrimString(tempchar); if (tempchar[0] == '-' && tempchar[1] == ' ') memmove(&tempchar[1], &tempchar[2], sizeof(TCHAR)*(_tcslen(&tempchar[2])+1)); // quit if the value obtained is N/A or not a number if ( !_tcscmp(tempchar, NODATA) || !_tcscmp(tempchar, _T("N/A"))) { _tcscpy(str, tempchar); return; } if ( !is_number(tempchar)) { _tcscpy(str, NODATA); return; } // convert the string to an integer temp = _ttof(tempchar); // convert all to F first if ( !_tcsicmp(unit, _T("C"))) temp = (temp*9/5)+32; else if ( !_tcsicmp(unit, _T("K"))) temp = ((temp-273.15)*9/5)+32; // convert to apporiate unit switch (opt.tUnit) { case 1: // rounding numToStr((temp-32)/9*5, tstr); if (opt.DoNotAppendUnit) wsprintf(str, _T("%s"), tstr); else wsprintf(str, _T("%s%sC"), tstr, opt.DegreeSign); break; case 2: numToStr(temp, tstr); if (opt.DoNotAppendUnit) wsprintf(str, _T("%s"), tstr); else wsprintf(str, _T("%s%sF"), tstr, opt.DegreeSign); break; } } // temperature conversion // tempchar = the string containing the pressure value // unit = the unit for pressure // return value = the converted pressure with unit; if fail, return the original string void GetPressure(TCHAR *tempchar, TCHAR *unit, TCHAR* str) { // unit can be kPa, hPa, mb, in, mm, torr double tempunit = 0, output; int intunit; // convert the string to a floating point number (always positive) // if it end up with 0, then it's not a number, return the original string and quit output = _ttof(tempchar); if (output == 0) { _tcscpy(str, tempchar); return; } // convert all to mb first if ( !_tcsicmp(unit, _T("KPA"))) tempunit = (double)output * 10; else if ( !_tcsicmp(unit, _T("HPA"))) tempunit = (double)output; else if ( !_tcsicmp(unit, _T("MB"))) tempunit = (double)output; else if ( !_tcsicmp(unit, _T("IN"))) tempunit = (double)output * 33.86388; else if ( !_tcsicmp(unit, _T("MM"))) tempunit = (double)output * 1.33322; else if ( !_tcsicmp(unit, _T("TORR"))) tempunit = (double)output * 1.33322; // convert to apporiate unit switch (opt.pUnit) { case 1: intunit = (int)(tempunit + 0.5); wsprintf(str, _T("%i.%i %s"), intunit/10, intunit%10, opt.DoNotAppendUnit ? _T("") : TranslateT("kPa")); break; case 2: intunit = (int)(tempunit + 0.5); wsprintf(str, _T("%i %s"), intunit, opt.DoNotAppendUnit ? _T("") : TranslateT("mb")); break; case 3: intunit = (int)((tempunit*10 / 33.86388) + 0.5); wsprintf(str, _T("%i.%i %s"), intunit/10, intunit%10, opt.DoNotAppendUnit ? _T("") : TranslateT("in")); break; case 4: intunit = (int)((tempunit*10 / 1.33322) + 0.5); wsprintf(str, _T("%i.%i %s"), intunit/10, intunit%10, opt.DoNotAppendUnit ? _T("") : TranslateT("mm")); break; default: _tcscpy(str, tempchar); break; } } // speed conversion // tempchar = the string containing the speed value // unit = the unit for speed // return value = the converted speed with unit; if fail, return _T("" void GetSpeed(TCHAR *tempchar, TCHAR *unit, TCHAR *str) { // unit can be km/h, mph, m/s, knots double tempunit; TCHAR tstr[20]; str[0] = 0; // convert the string into an integer (always positive) // if the result is 0, then the string is not a number, return _T("" tempunit = _ttof(tempchar); if (tempunit == 0 && tempchar[0] != '0') return; // convert all to m/s first if ( !_tcsicmp(unit, _T("KM/H"))) tempunit /= 3.6; // else if ( !_tcsicmp(unit, _T("M/S")) // tempunit = tempunit; else if ( !_tcsicmp(unit, _T("MPH"))) tempunit *= 0.44704; else if ( !_tcsicmp(unit, _T("KNOTS"))) tempunit *= 0.514444; // convert to apporiate unit switch (opt.wUnit) { case 1: numToStr(tempunit * 3.6, tstr); wsprintf(str, _T("%s %s"), tstr, opt.DoNotAppendUnit ? _T("") : TranslateT("km/h")); break; case 2: numToStr(tempunit, tstr); wsprintf(str, _T("%s %s"), tstr, opt.DoNotAppendUnit ? _T("") : TranslateT("m/s")); break; case 3: numToStr(tempunit / 0.44704, tstr); wsprintf(str, _T("%s %s"), tstr, opt.DoNotAppendUnit ? _T("") : TranslateT("mph")); break; case 4: numToStr(tempunit / 0.514444, tstr); wsprintf(str, _T("%s %s"), tstr, opt.DoNotAppendUnit ? _T("") : TranslateT("knots")); break; } } // distance conversion // tempchar = the string containing the distance value // unit = the unit for distance // return value = the converted distance with unit; if fail, return original string void GetDist(TCHAR *tempchar, TCHAR *unit, TCHAR *str) { // unit can be km, miles double tempunit = 0, output; int intunit; // convert the string to a floating point number (always positive) // if it end up with 0, then it's not a number, return the original string and quit output = _ttof(tempchar); if (output == 0) { _tcscpy(str, tempchar); return; } // convert all to km first if ( !_tcsicmp(unit, _T("KM"))) tempunit = (double)output; else if ( !_tcsicmp(unit, _T("MILES"))) tempunit = (double)output * 1.609; // convert to apporiate unit switch (opt.vUnit) { case 1: intunit = (int)((tempunit*10) + 0.5); wsprintf(str, _T("%i.%i %s"), intunit/10, intunit%10, opt.DoNotAppendUnit ? _T("") : TranslateT("km")); break; case 2: intunit = (int)((tempunit*10 / 1.609) + 0.5); wsprintf(str, _T("%i.%i %s"), intunit/10, intunit%10, opt.DoNotAppendUnit ? _T("") : TranslateT("miles")); break; default: _tcscpy(str, tempchar); break; } } // elevation conversion // tempchar = the string containing the elevation value // unit = the unit for elevation // return value = the converted elevation with unit; if fail, return original string void GetElev(TCHAR *tempchar, TCHAR *unit, TCHAR *str) { // unit can be ft, m double tempunit = 0, output; int intunit; // convert the string to a floating point number (always positive) // if it end up with 0, then it's not a number, return the original string and quit output = _ttof(tempchar); if (output == 0) { _tcscpy(str, tempchar); return; } // convert all to m first if ( !_tcsicmp(unit, _T("M"))) tempunit = (double)output; else if ( !_tcsicmp(unit, _T("FT"))) tempunit = (double)output / 3.28; // convert to apporiate unit switch (opt.eUnit) { case 1: intunit = (int)((tempunit*10 * 3.28) + 0.5); wsprintf(str, _T("%i.%i %s"), intunit/10, intunit%10, opt.DoNotAppendUnit ? _T("") : TranslateT("ft")); break; case 2: intunit = (int)((tempunit*10) + 0.5); wsprintf(str, _T("%i.%i %s"), intunit/10, intunit%10, opt.DoNotAppendUnit ? _T("") : TranslateT("m")); break; default: _tcscpy(str, tempchar); break; } } //============ CONDITION ICON ASSIGNMENT ============ // assign the contact icon (status) from the condition string // the description may be different between different sources // cond = the string for weather condition // return value = status for the icon (ONLINE, OFFLINE, etc) static const TCHAR *statusStr[10] = { _T("Lightning"), _T("Fog"), _T("Snow Shower"), _T("Snow"), _T("Rain Shower"), _T("Rain"), _T("Partly Cloudy"), _T("Cloudy"), _T("Sunny"), _T("N/A") }; static const WORD statusValue[10] = { LIGHT, FOG, SSHOWER, SNOW, RSHOWER, RAIN, PCLOUDY, CLOUDY, SUNNY, NA }; WORD GetIcon(const TCHAR* cond, WIDATA *Data) { int i; // set the icon using ini for (i=0; i<10; i++) if ( IsContainedInCondList(cond, &Data->CondList[i])) return statusValue[i]; // internal detection if ( _tcsstr(cond, _T("mainy sunny")) != NULL || _tcsstr(cond, _T("mainy clear")) != NULL || _tcsstr(cond, _T("partly cloudy")) != NULL || _tcsstr(cond, _T("mostly")) != NULL || _tcsstr(cond, _T("clouds")) != NULL) { return PCLOUDY; } else if ( _tcsstr(cond, _T("sunny")) != NULL || _tcsstr(cond, _T("clear")) != NULL || _tcsstr(cond, _T("fair")) != NULL) { return SUNNY; } else if ( _tcsstr(cond, _T("thunder")) != NULL || _tcsstr(cond, _T("t-storm")) != NULL) { return LIGHT; } else if ( _tcsstr(cond, _T("cloud")) != NULL || _tcsstr(cond, _T("overcast")) != NULL) { return CLOUDY; } else if ( _tcsstr(cond, _T("fog")) != NULL || _tcsstr(cond, _T("mist")) != NULL || _tcsstr(cond, _T("smoke")) != NULL || _tcsstr(cond, _T("sand")) != NULL || _tcsstr(cond, _T("dust")) != NULL || _tcsstr(cond, _T("haze")) != NULL) { return FOG; } else if ( (_tcsstr(cond, _T("shower")) != NULL && _tcsstr(cond, _T("snow")) != NULL) || _tcsstr(cond, _T("flurries")) != NULL) { return SSHOWER; } else if ( _tcsstr(cond, _T("rain shower")) != NULL || _tcsstr(cond, _T("shower")) != NULL) { return RSHOWER; } else if ( _tcsstr(cond, _T("snow")) != NULL || _tcsstr(cond, _T("ice")) != NULL || _tcsstr(cond, _T("freezing")) != NULL || _tcsstr(cond, _T("wintry")) != NULL) { return SNOW; } else if ( _tcsstr(cond, _T("drizzle")) != NULL || _tcsstr(cond, _T("rain")) != NULL) { return RAIN; } // set the icon using langpack for (i=0; i < 9; i++) { TCHAR LangPackStr[64], LangPackStr1[128]; int j = 0; do { j++; // using the format _T("# Weather #" mir_sntprintf(LangPackStr, SIZEOF(LangPackStr), _T("# Weather %s %i #"), statusStr[i], j); mir_sntprintf(LangPackStr1, SIZEOF(LangPackStr1), _T("%s"), TranslateTS(LangPackStr)); CharLowerBuff(LangPackStr1, (DWORD)_tcslen(LangPackStr1)); if (_tcsstr(cond, LangPackStr1) != NULL) return statusValue[i]; // loop until the translation string exists (ie, the translated string is differ from original) } while ( _tcscmp(TranslateTS(LangPackStr), LangPackStr)); } return NA; } //============ STRING CONVERSIONS ============ // this function convert the string to the format with 1 upper case followed by lower case char void CaseConv(TCHAR *str) { TCHAR *pstr; BOOL nextUp = TRUE; CharLowerBuff(str, (DWORD)_tcslen(str)); for(pstr = str; *pstr; pstr++) { if (*pstr == ' ' || *pstr == '-') nextUp = TRUE; else { TCHAR ch = *(TCHAR*)pstr; if (nextUp) *pstr = ( TCHAR )CharUpper((LPTSTR)ch); nextUp = FALSE; } } } // the next 2 functions are copied from miranda source // str = the string to modify void TrimString(char *str) { size_t len, start; len = strlen(str); while(len && (unsigned char)str[len-1] <= ' ') str[--len] = 0; for(start=0; (unsigned char)str[start] <= ' ' && str[start]; start++); memmove(str, str+start, len-start+1); } void TrimString(WCHAR *str) { size_t len, start; len = wcslen(str); while(len && (unsigned char)str[len-1] <= ' ') str[--len] = 0; for(start=0; (unsigned char)str[start] <= ' ' && str[start]; start++); memmove(str, str+start, (len-start+1)*sizeof(WCHAR)); } // convert \t to tab and \n to linefeed void ConvertBackslashes(char *str) { for (char *pstr=str; *pstr; pstr = CharNextA(pstr)) { if (*pstr == '\\') { switch(pstr[1]) { case 'n': *pstr = '\n'; break; case 't': *pstr = '\t'; break; default: *pstr = pstr[1]; break; } memmove(pstr+1, pstr+2, strlen(pstr+2)+1); } } } // replace spaces with _T("%20" // dis = original string // return value = the modified string with space -> _T("%20" char *GetSearchStr(char *dis) { char *pstr = dis; size_t len = strlen(dis); while (*pstr != 0) { if (*pstr == ' ') { memmove(pstr+3, pstr+1, len); memcpy(pstr, _T("%20"), 3); pstr += 2; } pstr++; len--; } return dis; } //============ ICON ASSIGNMENT ============ // make display and history strings // w = WEATHERINFO data to be parsed // dis = the string to parse // return value = the parsed string TCHAR* GetDisplay(WEATHERINFO *w, const TCHAR *dis, TCHAR* str) { TCHAR lpzDate[32], chr; char name[256], temp[2]; DBVARIANT dbv; size_t i; // Clear the string str[0] = 0; // looking character by character for (i=0; i < _tcslen(dis); i++) { // for the escape characters if (dis[i] == '\\') { i++; chr = dis[i]; switch (chr) { case '%': _tcscat(str, _T("%")); break; case 't': _tcscat(str, _T("\t")); break; case 'n': _tcscat(str, _T("\r\n")); break; case '\\': _tcscat(str, _T("\\")); break; } } // for the % varaibles else if (dis[i] == '%') { i++; chr = dis[i]; // turn capitalized characters to small case if (chr < 'a' && chr != '[' && chr != '%') chr = (char)((int)chr + 32); switch (chr) { case 'c': _tcscat(str, w->cond); break; case 'd': // get the current date GetDateFormat(LOCALE_USER_DEFAULT, DATE_SHORTDATE, NULL, NULL, lpzDate, SIZEOF(lpzDate)); _tcscat(str, lpzDate); break; case 'e': _tcscat(str, w->dewpoint); break; case 'f': _tcscat(str, w->feel); break; case 'h': _tcscat(str, w->high); break; case 'i': _tcscat(str, w->winddir); break; case 'l': _tcscat(str, w->low); break; case 'm': _tcscat(str, w->humid); break; case 'n': _tcscat(str, w->city); break; case 'p': _tcscat(str, w->pressure); break; case 'r': _tcscat(str, w->sunrise); break; case 's': _tcscat(str, w->id); break; case 't': _tcscat(str, w->temp); break; case 'u': if (_tcscmp(w->update, NODATA)) _tcscat(str, w->update); else _tcscat(str, TranslateT("")); break; case 'v': _tcscat(str, w->vis); break; case 'w': _tcscat(str, w->wind); break; case 'y': _tcscat(str, w->sunset); break; case '%': _tcscat(str, _T("%")); break; case '[': // custom variables i++; name[0] = 0; // read the entire variable name while (dis[i] != ']' && i < _tcslen(dis)) { wsprintfA(temp, "%c", dis[i++]); strcat(name, temp); } // access the database to get its value if ( !DBGetContactSettingTString(w->hContact, WEATHERCONDITION, name, &dbv)) { if (dbv.ptszVal != TranslateTS(NODATA) && dbv.ptszVal != TranslateT("")) _tcscat(str, dbv.ptszVal); db_free(&dbv); } break; } } // if the character is not a variable, write the original character to the new string else { wsprintf( lpzDate, _T("%c"), dis[i]); _tcscat(str, lpzDate); } } return str; } TCHAR svcReturnText[MAX_TEXT_SIZE]; INT_PTR GetDisplaySvcFunc(WPARAM wParam, LPARAM lParam) { WEATHERINFO winfo = LoadWeatherInfo((HANDLE)wParam); return (INT_PTR)GetDisplay(&winfo, (TCHAR*)lParam, svcReturnText); } //============ ID MANAGEMENT ============ // get service data module internal name // mod/id <- the mod part // pszID = original 2-part id, return the service internal name void GetSvc(TCHAR *pszID) { TCHAR *chop = _tcsstr(pszID, _T("/")); if (chop != NULL) *chop = '\0'; else pszID[0] = 0; } // get the id use for update without the service internal name // mod/id <- the id part // pszID = original 2-part id, return the single part id void GetID(TCHAR *pszID) { TCHAR *chop = _tcsstr(pszID, _T("/")); if (chop != NULL) _tcscpy(pszID, chop+1); else pszID[0] = 0; } //============ WEATHER ERROR CODE ============ // Get the text when an error code is specified // code = the error code obtained when updating weather // str = the string for the error TCHAR *GetError(int code) { TCHAR *str, str2[100]; switch (code) { case 10: str = E10; break; case 11: str = E11; break; case 12: str = E12; break; case 20: str = E20; break; case 30: str = E30; break; case 40: str = E40; break; case 42: str = E42; break; case 43: str = E43; break; case 99: str = E99; break; case 204: str = E204; break; case 301: str = E301; break; case 305: str = E305; break; case 307: str = E307; break; case 400: str = E400; break; case 401: str = E401; break; case 402: str = E402; break; case 403: str = E403; break; case 404: str = E404; break; case 405: str = E405; break; case 407: str = E407; break; case 410: str = E410; break; case 500: str = E500; break; case 502: str = E502; break; case 503: str = E503; break; case 504: str = E504; break; default: mir_sntprintf(str2, SIZEOF(str2), TranslateT("HTTP Error %i"), code); str = str2; break; } return str; }