// Copyright (C) 2016 and later: Unicode, Inc. and others. // License & terms of use: http://www.unicode.org/copyright.html /* ********************************************************************** * Copyright (c) 2003-2014, International Business Machines * Corporation and others. All Rights Reserved. ********************************************************************** * Author: Alan Liu * Created: July 10 2003 * Since: ICU 2.8 ********************************************************************** */ #include "tzfile.h" // from Olson tzcode archive, copied to this dir #ifdef WIN32 #include <windows.h> #undef min // windows.h/STL conflict #undef max // windows.h/STL conflict // "identifier was truncated to 'number' characters" warning #pragma warning(disable: 4786) #else #include <unistd.h> #include <stdio.h> #include <dirent.h> #include <string.h> #include <sys/stat.h> #endif #include <algorithm> #include <cassert> #include <ctime> #include <fstream> #include <iomanip> #include <iostream> #include <iterator> #include <limits> #include <map> #include <set> #include <sstream> #include <sstream> #include <stdexcept> #include <string> #include <vector> #include "tz2icu.h" #include "unicode/uversion.h" using namespace std; bool ICU44PLUS = TRUE; string TZ_RESOURCE_NAME = ICU_TZ_RESOURCE; //-------------------------------------------------------------------- // Time utilities //-------------------------------------------------------------------- const int64_t SECS_PER_YEAR = 31536000; // 365 days const int64_t SECS_PER_LEAP_YEAR = 31622400; // 366 days const int64_t LOWEST_TIME32 = (int64_t)((int32_t)0x80000000); const int64_t HIGHEST_TIME32 = (int64_t)((int32_t)0x7fffffff); bool isLeap(int32_t y) { return (y%4 == 0) && ((y%100 != 0) || (y%400 == 0)); // Gregorian } int64_t secsPerYear(int32_t y) { return isLeap(y) ? SECS_PER_LEAP_YEAR : SECS_PER_YEAR; } /** * Given a calendar year, return the GMT epoch seconds for midnight * GMT of January 1 of that year. yearToSeconds(1970) == 0. */ int64_t yearToSeconds(int32_t year) { // inefficient but foolproof int64_t s = 0; int32_t y = 1970; while (y < year) { s += secsPerYear(y++); } while (y > year) { s -= secsPerYear(--y); } return s; } /** * Given 1970 GMT epoch seconds, return the calendar year containing * that time. secondsToYear(0) == 1970. */ int32_t secondsToYear(int64_t seconds) { // inefficient but foolproof int32_t y = 1970; int64_t s = 0; if (seconds >= 0) { for (;;) { s += secsPerYear(y++); if (s > seconds) break; } --y; } else { for (;;) { s -= secsPerYear(--y); if (s <= seconds) break; } } return y; } //-------------------------------------------------------------------- // Types //-------------------------------------------------------------------- struct FinalZone; struct FinalRule; struct SimplifiedZoneType; // A transition from one ZoneType to another // Minimal size = 5 bytes (4+1) struct Transition { int64_t time; // seconds, 1970 epoch int32_t type; // index into 'ZoneInfo.types' 0..255 Transition(int64_t _time, int32_t _type) { time = _time; type = _type; } }; // A behavior mode (what zic calls a 'type') of a time zone. // Minimal size = 6 bytes (4+1+3bits) // SEE: SimplifiedZoneType struct ZoneType { int64_t rawoffset; // raw seconds offset from GMT int64_t dstoffset; // dst seconds offset from GMT // We don't really need any of the following, but they are // retained for possible future use. See SimplifiedZoneType. int32_t abbr; // index into ZoneInfo.abbrs 0..n-1 bool isdst; bool isstd; bool isgmt; ZoneType(const SimplifiedZoneType&); // used by optimizeTypeList ZoneType() : rawoffset(-1), dstoffset(-1), abbr(-1) {} // A restricted equality, of just the raw and dst offset bool matches(const ZoneType& other) { return rawoffset == other.rawoffset && dstoffset == other.dstoffset; } }; // A collection of transitions from one ZoneType to another, together // with a list of the ZoneTypes. A ZoneInfo object may have a long // list of transitions between a smaller list of ZoneTypes. // // This object represents the contents of a single zic-created // zoneinfo file. struct ZoneInfo { vector<Transition> transitions; vector<ZoneType> types; vector<string> abbrs; string finalRuleID; int32_t finalOffset; int32_t finalYear; // -1 if none // If this is an alias, then all other fields are meaningless, and // this field will point to the "real" zone 0..n-1. int32_t aliasTo; // -1 if this is a "real" zone // If there are aliases TO this zone, then the following set will // contain their index numbers (each index >= 0). set<int32_t> aliases; ZoneInfo() : finalYear(-1), aliasTo(-1) {} void mergeFinalData(const FinalZone& fz); void optimizeTypeList(); // Set this zone to be an alias TO another zone. void setAliasTo(int32_t index); // Clear the list of aliases OF this zone. void clearAliases(); // Add an alias to the list of aliases OF this zone. void addAlias(int32_t index); // Is this an alias to another zone? bool isAlias() const { return aliasTo >= 0; } // Retrieve alias list const set<int32_t>& getAliases() const { return aliases; } void print(ostream& os, const string& id) const; }; void ZoneInfo::clearAliases() { assert(aliasTo < 0); aliases.clear(); } void ZoneInfo::addAlias(int32_t index) { assert(aliasTo < 0 && index >= 0 && aliases.find(index) == aliases.end()); aliases.insert(index); } void ZoneInfo::setAliasTo(int32_t index) { assert(index >= 0); assert(aliases.size() == 0); aliasTo = index; } typedef map<string, ZoneInfo> ZoneMap; typedef ZoneMap::const_iterator ZoneMapIter; //-------------------------------------------------------------------- // ZONEINFO //-------------------------------------------------------------------- // Global map holding all our ZoneInfo objects, indexed by id. ZoneMap ZONEINFO; //-------------------------------------------------------------------- // zoneinfo file parsing //-------------------------------------------------------------------- // Read zic-coded 32-bit integer from file int64_t readcoded(ifstream& file, int64_t minv=numeric_limits<int64_t>::min(), int64_t maxv=numeric_limits<int64_t>::max()) { unsigned char buf[4]; // must be UNSIGNED int64_t val=0; file.read((char*)buf, 4); for(int32_t i=0,shift=24;i<4;++i,shift-=8) { val |= buf[i] << shift; } if (val < minv || val > maxv) { ostringstream os; os << "coded value out-of-range: " << val << ", expected [" << minv << ", " << maxv << "]"; throw out_of_range(os.str()); } return val; } // Read zic-coded 64-bit integer from file int64_t readcoded64(ifstream& file, int64_t minv=numeric_limits<int64_t>::min(), int64_t maxv=numeric_limits<int64_t>::max()) { unsigned char buf[8]; // must be UNSIGNED int64_t val=0; file.read((char*)buf, 8); for(int32_t i=0,shift=56;i<8;++i,shift-=8) { val |= (int64_t)buf[i] << shift; } if (val < minv || val > maxv) { ostringstream os; os << "coded value out-of-range: " << val << ", expected [" << minv << ", " << maxv << "]"; throw out_of_range(os.str()); } return val; } // Read a boolean value bool readbool(ifstream& file) { char c; file.read(&c, 1); if (c!=0 && c!=1) { ostringstream os; os << "boolean value out-of-range: " << (int32_t)c; throw out_of_range(os.str()); } return (c!=0); } /** * Read the zoneinfo file structure (see tzfile.h) into a ZoneInfo * @param file an already-open file stream */ void readzoneinfo(ifstream& file, ZoneInfo& info, bool is64bitData) { int32_t i; // Check for TZ_ICU_MAGIC signature at file start. If we get a // signature mismatch, it means we're trying to read a file which // isn't a ICU-modified-zic-created zoneinfo file. Typically this // means the user is passing in a "normal" zoneinfo directory, or // a zoneinfo directory that is polluted with other files, or that // the user passed in the wrong directory. char buf[32]; file.read(buf, 4); if (strncmp(buf, TZ_ICU_MAGIC, 4) != 0) { throw invalid_argument("TZ_ICU_MAGIC signature missing"); } // skip additional Olson byte version file.read(buf, 1); // if '\0', we have just one copy of data, if '2' or '3', there is additional // 64 bit version at the end. if(buf[0]!=0 && buf[0]!='2' && buf[0]!='3') { throw invalid_argument("Bad Olson version info"); } // Read reserved bytes. The first of these will be a version byte. file.read(buf, 15); if (*(ICUZoneinfoVersion*)&buf != TZ_ICU_VERSION) { throw invalid_argument("File version mismatch"); } // Read array sizes int64_t isgmtcnt = readcoded(file, 0); int64_t isdstcnt = readcoded(file, 0); int64_t leapcnt = readcoded(file, 0); int64_t timecnt = readcoded(file, 0); int64_t typecnt = readcoded(file, 0); int64_t charcnt = readcoded(file, 0); // Confirm sizes that we assume to be equal. These assumptions // are drawn from a reading of the zic source (2003a), so they // should hold unless the zic source changes. if (isgmtcnt != typecnt || isdstcnt != typecnt) { throw invalid_argument("count mismatch between tzh_ttisgmtcnt, tzh_ttisdstcnt, tth_typecnt"); } // Used temporarily to store transition times and types. We need // to do this because the times and types are stored in two // separate arrays. vector<int64_t> transitionTimes(timecnt, -1); // temporary vector<int32_t> transitionTypes(timecnt, -1); // temporary // Read transition times for (i=0; i<timecnt; ++i) { if (is64bitData) { transitionTimes[i] = readcoded64(file); } else { transitionTimes[i] = readcoded(file); } } // Read transition types for (i=0; i<timecnt; ++i) { unsigned char c; file.read((char*) &c, 1); int32_t t = (int32_t) c; if (t < 0 || t >= typecnt) { ostringstream os; os << "illegal type: " << t << ", expected [0, " << (typecnt-1) << "]"; throw out_of_range(os.str()); } transitionTypes[i] = t; } // Build transitions vector out of corresponding times and types. bool insertInitial = false; if (is64bitData && !ICU44PLUS) { if (timecnt > 0) { int32_t minidx = -1; for (i=0; i<timecnt; ++i) { if (transitionTimes[i] < LOWEST_TIME32) { if (minidx == -1 || transitionTimes[i] > transitionTimes[minidx]) { // Preserve the latest transition before the 32bit minimum time minidx = i; } } else if (transitionTimes[i] > HIGHEST_TIME32) { // Skipping the rest of the transition data. We cannot put such // transitions into zoneinfo.res, because data is limited to singed // 32bit int by the ICU resource bundle. break; } else { info.transitions.push_back(Transition(transitionTimes[i], transitionTypes[i])); } } if (minidx != -1) { // If there are any transitions before the 32bit minimum time, // put the type information with the 32bit minimum time vector<Transition>::iterator itr = info.transitions.begin(); info.transitions.insert(itr, Transition(LOWEST_TIME32, transitionTypes[minidx])); } else { // Otherwise, we need insert the initial type later insertInitial = true; } } } else { for (i=0; i<timecnt; ++i) { info.transitions.push_back(Transition(transitionTimes[i], transitionTypes[i])); } } // Read types (except for the isdst and isgmt flags, which come later (why??)) for (i=0; i<typecnt; ++i) { ZoneType type; type.rawoffset = readcoded(file); type.dstoffset = readcoded(file); type.isdst = readbool(file); unsigned char c; file.read((char*) &c, 1); type.abbr = (int32_t) c; if (type.isdst != (type.dstoffset != 0)) { throw invalid_argument("isdst does not reflect dstoffset"); } info.types.push_back(type); } assert(info.types.size() == (unsigned) typecnt); if (insertInitial) { assert(timecnt > 0); assert(typecnt > 0); int32_t initialTypeIdx = -1; // Check if the first type is not dst if (info.types.at(0).dstoffset != 0) { // Initial type's rawoffset is same with the rawoffset after the // first transition, but no DST is observed. int64_t rawoffset0 = (info.types.at(info.transitions.at(0).type)).rawoffset; // Look for matching type for (i=0; i<(int32_t)info.types.size(); ++i) { if (info.types.at(i).rawoffset == rawoffset0 && info.types.at(i).dstoffset == 0) { initialTypeIdx = i; break; } } } else { initialTypeIdx = 0; } assert(initialTypeIdx >= 0); // Add the initial type associated with the lowest int32 time vector<Transition>::iterator itr = info.transitions.begin(); info.transitions.insert(itr, Transition(LOWEST_TIME32, initialTypeIdx)); } // Read the abbreviation string if (charcnt) { // All abbreviations are concatenated together, with a 0 at // the end of each abbr. char* str = new char[charcnt + 8]; file.read(str, charcnt); // Split abbreviations apart into individual strings. Record // offset of each abbr in a vector. vector<int32_t> abbroffset; char *limit=str+charcnt; for (char* p=str; p<limit; ++p) { char* start = p; while (*p != 0) ++p; info.abbrs.push_back(string(start, p-start)); abbroffset.push_back(start-str); } // Remap all the abbrs. Old value is offset into concatenated // raw abbr strings. New value is index into vector of // strings. E.g., 0,5,10,14 => 0,1,2,3. // Keep track of which abbreviations get used. vector<bool> abbrseen(abbroffset.size(), false); for (vector<ZoneType>::iterator it=info.types.begin(); it!=info.types.end(); ++it) { vector<int32_t>::const_iterator x= find(abbroffset.begin(), abbroffset.end(), it->abbr); if (x==abbroffset.end()) { // TODO: Modify code to add a new string to the end of // the abbr list when a middle offset is given, e.g., // "abc*def*" where * == '\0', take offset of 1 and // make the array "abc", "def", "bc", and translate 1 // => 2. NOT CRITICAL since we don't even use the // abbr at this time. #if 0 // TODO: Re-enable this warning if we start using // the Olson abbr data, or if the above TODO is completed. ostringstream os; os << "Warning: unusual abbr offset " << it->abbr << ", expected one of"; for (vector<int32_t>::const_iterator y=abbroffset.begin(); y!=abbroffset.end(); ++y) { os << ' ' << *y; } cerr << os.str() << "; using 0" << endl; #endif it->abbr = 0; } else { int32_t index = x - abbroffset.begin(); it->abbr = index; abbrseen[index] = true; } } for (int32_t ii=0;ii<(int32_t) abbrseen.size();++ii) { if (!abbrseen[ii]) { cerr << "Warning: unused abbreviation: " << ii << endl; } } } // Read leap second info, if any. // *** We discard leap second data. *** for (i=0; i<leapcnt; ++i) { readcoded(file); // transition time readcoded(file); // total correction after above } // Read isstd flags for (i=0; i<typecnt; ++i) info.types[i].isstd = readbool(file); // Read isgmt flags for (i=0; i<typecnt; ++i) info.types[i].isgmt = readbool(file); } //-------------------------------------------------------------------- // Directory and file reading //-------------------------------------------------------------------- /** * Process a single zoneinfo file, adding the data to ZONEINFO * @param path the full path to the file, e.g., ".\zoneinfo\America\Los_Angeles" * @param id the zone ID, e.g., "America/Los_Angeles" */ void handleFile(string path, string id) { // Check for duplicate id if (ZONEINFO.find(id) != ZONEINFO.end()) { ostringstream os; os << "duplicate zone ID: " << id; throw invalid_argument(os.str()); } ifstream file(path.c_str(), ios::in | ios::binary); if (!file) { throw invalid_argument("can't open file"); } // eat 32bit data part ZoneInfo info; readzoneinfo(file, info, false); // Check for errors if (!file) { throw invalid_argument("read error"); } // we only use 64bit part ZoneInfo info64; readzoneinfo(file, info64, true); bool alldone = false; int64_t eofPos = (int64_t) file.tellg(); // '\n' + <envvar string> + '\n' after the 64bit version data char ch = file.get(); if (ch == 0x0a) { bool invalidchar = false; while (file.get(ch)) { if (ch == 0x0a) { break; } if (ch < 0x20) { // must be printable ascii invalidchar = true; break; } } if (!invalidchar) { eofPos = (int64_t) file.tellg(); file.seekg(0, ios::end); eofPos = eofPos - (int64_t) file.tellg(); if (eofPos == 0) { alldone = true; } } } if (!alldone) { ostringstream os; os << (-eofPos) << " unprocessed bytes at end"; throw invalid_argument(os.str()); } ZONEINFO[id] = info64; } /** * Recursively scan the given directory, calling handleFile() for each * file in the tree. The user should call with the root directory and * a prefix of "". The function will call itself with non-empty * prefix values. */ #ifdef WIN32 void scandir(string dirname, string prefix="") { HANDLE hList; WIN32_FIND_DATA FileData; // Get the first file hList = FindFirstFile((dirname + "\\*").c_str(), &FileData); if (hList == INVALID_HANDLE_VALUE) { cerr << "Error: Invalid directory: " << dirname << endl; exit(1); } for (;;) { string name(FileData.cFileName); string path(dirname + "\\" + name); if (FileData.dwFileAttributes & FILE_ATTRIBUTE_DIRECTORY) { if (name != "." && name != "..") { scandir(path, prefix + name + "/"); } } else { try { string id = prefix + name; handleFile(path, id); } catch (const exception& e) { cerr << "Error: While processing \"" << path << "\", " << e.what() << endl; exit(1); } } if (!FindNextFile(hList, &FileData)) { if (GetLastError() == ERROR_NO_MORE_FILES) { break; } // else...? } } FindClose(hList); } #else void scandir(string dir, string prefix="") { DIR *dp; struct dirent *dir_entry; struct stat stat_info; char pwd[512]; vector<string> subdirs; vector<string> subfiles; if ((dp = opendir(dir.c_str())) == NULL) { cerr << "Error: Invalid directory: " << dir << endl; exit(1); } if (!getcwd(pwd, sizeof(pwd))) { cerr << "Error: Directory name too long" << endl; exit(1); } chdir(dir.c_str()); while ((dir_entry = readdir(dp)) != NULL) { string name = dir_entry->d_name; string path = dir + "/" + name; lstat(dir_entry->d_name,&stat_info); if (S_ISDIR(stat_info.st_mode)) { if (name != "." && name != "..") { subdirs.push_back(path); subdirs.push_back(prefix + name + "/"); // scandir(path, prefix + name + "/"); } } else { try { string id = prefix + name; subfiles.push_back(path); subfiles.push_back(id); // handleFile(path, id); } catch (const exception& e) { cerr << "Error: While processing \"" << path << "\", " << e.what() << endl; exit(1); } } } closedir(dp); chdir(pwd); for(int32_t i=0;i<(int32_t)subfiles.size();i+=2) { try { handleFile(subfiles[i], subfiles[i+1]); } catch (const exception& e) { cerr << "Error: While processing \"" << subfiles[i] << "\", " << e.what() << endl; exit(1); } } for(int32_t i=0;i<(int32_t)subdirs.size();i+=2) { scandir(subdirs[i], subdirs[i+1]); } } #endif //-------------------------------------------------------------------- // Final zone and rule info //-------------------------------------------------------------------- /** * Read and discard the current line. */ void consumeLine(istream& in) { int32_t c; do { c = in.get(); } while (c != EOF && c != '\n'); } enum { DOM = 0, DOWGEQ = 1, DOWLEQ = 2 }; const char* TIME_MODE[] = {"w", "s", "u"}; // Allow 29 days in February because zic outputs February 29 // for rules like "last Sunday in February". const int32_t MONTH_LEN[] = {31,29,31,30,31,30,31,31,30,31,30,31}; const int32_t HOUR = 3600; struct FinalZone { int32_t offset; // raw offset int32_t year; // takes effect for y >= year string ruleid; set<string> aliases; FinalZone(int32_t _offset, int32_t _year, const string& _ruleid) : offset(_offset), year(_year), ruleid(_ruleid) { if (offset <= -16*HOUR || offset >= 16*HOUR) { ostringstream os; os << "Invalid input offset " << offset << " for year " << year << " and rule ID " << ruleid; throw invalid_argument(os.str()); } if (year < 1900) { ostringstream os; os << "Invalid input year " << year << " with offset " << offset << " and rule ID " << ruleid; throw invalid_argument(os.str()); } } FinalZone() : offset(-1), year(-1) {} void addLink(const string& alias) { if (aliases.find(alias) != aliases.end()) { ostringstream os; os << "Duplicate alias " << alias; throw invalid_argument(os.str()); } aliases.insert(alias); } }; struct FinalRulePart { int32_t mode; int32_t month; int32_t dom; int32_t dow; int32_t time; int32_t offset; // dst offset, usually either 0 or 1:00 // Isstd and isgmt only have 3 valid states, corresponding to local // wall time, local standard time, and GMT standard time. // Here is how the isstd & isgmt flags are set by zic: //| case 's': /* Standard */ //| rp->r_todisstd = TRUE; //| rp->r_todisgmt = FALSE; //| case 'w': /* Wall */ //| rp->r_todisstd = FALSE; //| rp->r_todisgmt = FALSE; //| case 'g': /* Greenwich */ //| case 'u': /* Universal */ //| case 'z': /* Zulu */ //| rp->r_todisstd = TRUE; //| rp->r_todisgmt = TRUE; bool isstd; bool isgmt; bool isset; // used during building; later ignored FinalRulePart() : isset(false) {} void set(const string& id, const string& _mode, int32_t _month, int32_t _dom, int32_t _dow, int32_t _time, bool _isstd, bool _isgmt, int32_t _offset) { if (isset) { throw invalid_argument("FinalRulePart set twice"); } isset = true; if (_mode == "DOWLEQ") { mode = DOWLEQ; } else if (_mode == "DOWGEQ") { mode = DOWGEQ; } else if (_mode == "DOM") { mode = DOM; } else { throw invalid_argument("Unrecognized FinalRulePart mode"); } month = _month; dom = _dom; dow = _dow; time = _time; isstd = _isstd; isgmt = _isgmt; offset = _offset; ostringstream os; if (month < 0 || month >= 12) { os << "Invalid input month " << month; } if (dom < 1 || dom > MONTH_LEN[month]) { os << "Invalid input day of month " << dom; } if (mode != DOM && (dow < 0 || dow >= 7)) { os << "Invalid input day of week " << dow; } if (offset < 0 || offset > (2 * HOUR)) { os << "Invalid input offset " << offset; } if (isgmt && !isstd) { os << "Invalid input isgmt && !isstd"; } if (!os.str().empty()) { os << " for rule " << id << _mode << month << dom << dow << time << isstd << isgmt << offset; throw invalid_argument(os.str()); } } /** * Return the time mode as an ICU SimpleTimeZone int from 0..2; * see simpletz.h. */ int32_t timemode() const { if (isgmt) { assert(isstd); return 2; // gmt standard } if (isstd) { return 1; // local standard } return 0; // local wall } // The SimpleTimeZone encoding method for rules is as follows: // stz_dowim stz_dow // DOM: dom 0 // DOWGEQ: dom -(dow+1) // DOWLEQ: -dom -(dow+1) // E.g., to encode Mon>=7, use stz_dowim=7, stz_dow=-2 // to encode Mon<=7, use stz_dowim=-7, stz_dow=-2 // to encode 7, use stz_dowim=7, stz_dow=0 // Note that for this program and for SimpleTimeZone, 0==Jan, // but for this program 0==Sun while for SimpleTimeZone 1==Sun. /** * Return a "dowim" param suitable for SimpleTimeZone. */ int32_t stz_dowim() const { return (mode == DOWLEQ) ? -dom : dom; } /** * Return a "dow" param suitable for SimpleTimeZone. */ int32_t stz_dow() const { return (mode == DOM) ? 0 : -(dow+1); } }; struct FinalRule { FinalRulePart part[2]; bool isset() const { return part[0].isset && part[1].isset; } void print(ostream& os) const; }; map<string,FinalZone> finalZones; map<string,FinalRule> finalRules; map<string, set<string> > links; map<string, string> reverseLinks; map<string, string> linkSource; // id => "Olson link" or "ICU alias" /** * Predicate used to find FinalRule objects that do not have both * sub-parts set (indicating an error in the input file). */ bool isNotSet(const pair<const string,FinalRule>& p) { return !p.second.isset(); } /** * Predicate used to find FinalZone objects that do not map to a known * rule (indicating an error in the input file). */ bool mapsToUnknownRule(const pair<const string,FinalZone>& p) { return finalRules.find(p.second.ruleid) == finalRules.end(); } /** * This set is used to make sure each rule in finalRules is used at * least once. First we populate it with all the rules from * finalRules; then we remove all the rules referred to in * finaleZones. */ set<string> ruleIDset; void insertRuleID(const pair<string,FinalRule>& p) { ruleIDset.insert(p.first); } void eraseRuleID(const pair<string,FinalZone>& p) { ruleIDset.erase(p.second.ruleid); } /** * Populate finalZones and finalRules from the given istream. */ void readFinalZonesAndRules(istream& in) { for (;;) { string token; in >> token; if (in.eof() || !in) { break; } else if (token == "zone") { // zone Africa/Cairo 7200 1995 Egypt # zone Africa/Cairo, offset 7200, year >= 1995, rule Egypt (0) string id, ruleid; int32_t offset, year; in >> id >> offset >> year >> ruleid; consumeLine(in); finalZones[id] = FinalZone(offset, year, ruleid); } else if (token == "rule") { // rule US DOWGEQ 3 1 0 7200 0 0 3600 # 52: US, file data/northamerica, line 119, mode DOWGEQ, April, dom 1, Sunday, time 7200, isstd 0, isgmt 0, offset 3600 // rule US DOWLEQ 9 31 0 7200 0 0 0 # 53: US, file data/northamerica, line 114, mode DOWLEQ, October, dom 31, Sunday, time 7200, isstd 0, isgmt 0, offset 0 string id, mode; int32_t month, dom, dow, time, offset; bool isstd, isgmt; in >> id >> mode >> month >> dom >> dow >> time >> isstd >> isgmt >> offset; consumeLine(in); FinalRule& fr = finalRules[id]; int32_t p = fr.part[0].isset ? 1 : 0; fr.part[p].set(id, mode, month, dom, dow, time, isstd, isgmt, offset); } else if (token == "link") { string fromid, toid; // fromid == "real" zone, toid == alias in >> fromid >> toid; // DO NOT consumeLine(in); if (finalZones.find(toid) != finalZones.end()) { throw invalid_argument("Bad link: `to' id is a \"real\" zone"); } links[fromid].insert(toid); reverseLinks[toid] = fromid; linkSource[fromid] = "Olson link"; linkSource[toid] = "Olson link"; } else if (token.length() > 0 && token[0] == '#') { consumeLine(in); } else { throw invalid_argument("Unrecognized keyword"); } } if (!in.eof() && !in) { throw invalid_argument("Parse failure"); } // Perform validity check: Each rule should have data for 2 parts. if (count_if(finalRules.begin(), finalRules.end(), isNotSet) != 0) { throw invalid_argument("One or more incomplete rule pairs"); } // Perform validity check: Each zone should map to a known rule. if (count_if(finalZones.begin(), finalZones.end(), mapsToUnknownRule) != 0) { throw invalid_argument("One or more zones refers to an unknown rule"); } // Perform validity check: Each rule should be referred to by a zone. ruleIDset.clear(); for_each(finalRules.begin(), finalRules.end(), insertRuleID); for_each(finalZones.begin(), finalZones.end(), eraseRuleID); if (ruleIDset.size() != 0) { throw invalid_argument("Unused rules"); } } //-------------------------------------------------------------------- // Resource bundle output //-------------------------------------------------------------------- // SEE olsontz.h FOR RESOURCE BUNDLE DATA LAYOUT void ZoneInfo::print(ostream& os, const string& id) const { // Implement compressed format #2: os << " /* " << id << " */ "; if (aliasTo >= 0) { assert(aliases.size() == 0); os << ":int { " << aliasTo << " } "; // No endl - save room for comment. return; } if (ICU44PLUS) { os << ":table {" << endl; } else { os << ":array {" << endl; } vector<Transition>::const_iterator trn; vector<ZoneType>::const_iterator typ; bool first; if (ICU44PLUS) { trn = transitions.begin(); // pre 32bit transitions if (trn != transitions.end() && trn->time < LOWEST_TIME32) { os << " transPre32:intvector { "; for (first = true; trn != transitions.end() && trn->time < LOWEST_TIME32; ++trn) { if (!first) { os<< ", "; } first = false; os << (int32_t)(trn->time >> 32) << ", " << (int32_t)(trn->time & 0x00000000ffffffff); } os << " }" << endl; } // 32bit transtions if (trn != transitions.end() && trn->time < HIGHEST_TIME32) { os << " trans:intvector { "; for (first = true; trn != transitions.end() && trn->time < HIGHEST_TIME32; ++trn) { if (!first) { os << ", "; } first = false; os << trn->time; } os << " }" << endl; } // post 32bit transitons if (trn != transitions.end()) { os << " transPost32:intvector { "; for (first = true; trn != transitions.end(); ++trn) { if (!first) { os<< ", "; } first = false; os << (int32_t)(trn->time >> 32) << ", " << (int32_t)(trn->time & 0x00000000ffffffff); } os << " }" << endl; } } else { os << " :intvector { "; for (trn = transitions.begin(), first = true; trn != transitions.end(); ++trn) { if (!first) os << ", "; first = false; os << trn->time; } os << " }" << endl; } first=true; if (ICU44PLUS) { os << " typeOffsets:intvector { "; } else { os << " :intvector { "; } for (typ = types.begin(); typ != types.end(); ++typ) { if (!first) os << ", "; first = false; os << typ->rawoffset << ", " << typ->dstoffset; } os << " }" << endl; if (ICU44PLUS) { if (transitions.size() != 0) { os << " typeMap:bin { \"" << hex << setfill('0'); for (trn = transitions.begin(); trn != transitions.end(); ++trn) { os << setw(2) << trn->type; } os << dec << "\" }" << endl; } } else { os << " :bin { \"" << hex << setfill('0'); for (trn = transitions.begin(); trn != transitions.end(); ++trn) { os << setw(2) << trn->type; } os << dec << "\" }" << endl; } // Final zone info, if any if (finalYear != -1) { if (ICU44PLUS) { os << " finalRule { \"" << finalRuleID << "\" }" << endl; os << " finalRaw:int { " << finalOffset << " }" << endl; os << " finalYear:int { " << finalYear << " }" << endl; } else { os << " \"" << finalRuleID << "\"" << endl; os << " :intvector { " << finalOffset << ", " << finalYear << " }" << endl; } } // Alias list, if any if (aliases.size() != 0) { first = true; if (ICU44PLUS) { os << " links:intvector { "; } else { os << " :intvector { "; } for (set<int32_t>::const_iterator i=aliases.begin(); i!=aliases.end(); ++i) { if (!first) os << ", "; first = false; os << *i; } os << " }" << endl; } os << " } "; // no trailing 'endl', so comments can be placed. } inline ostream& operator<<(ostream& os, const ZoneMap& zoneinfo) { int32_t c = 0; for (ZoneMapIter it = zoneinfo.begin(); it != zoneinfo.end(); ++it) { if(c && !ICU44PLUS) os << ","; it->second.print(os, it->first); os << "//Z#" << c++ << endl; } return os; } // print the string list ostream& printStringList( ostream& os, const ZoneMap& zoneinfo) { int32_t n = 0; // count int32_t col = 0; // column os << " Names {" << endl << " "; for (ZoneMapIter it = zoneinfo.begin(); it != zoneinfo.end(); ++it) { if(n) { os << ","; col ++; } const string& id = it->first; os << "\"" << id << "\""; col += id.length() + 2; if(col >= 50) { os << " // " << n << endl << " "; col = 0; } n++; } os << " // " << (n-1) << endl << " }" << endl; return os; } //-------------------------------------------------------------------- // main //-------------------------------------------------------------------- // Unary predicate for finding transitions after a given time bool isAfter(const Transition t, int64_t thresh) { return t.time >= thresh; } /** * A zone type that contains only the raw and dst offset. Used by the * optimizeTypeList() method. */ struct SimplifiedZoneType { int64_t rawoffset; int64_t dstoffset; SimplifiedZoneType() : rawoffset(-1), dstoffset(-1) {} SimplifiedZoneType(const ZoneType& t) : rawoffset(t.rawoffset), dstoffset(t.dstoffset) {} bool operator<(const SimplifiedZoneType& t) const { return rawoffset < t.rawoffset || (rawoffset == t.rawoffset && dstoffset < t.dstoffset); } }; /** * Construct a ZoneType from a SimplifiedZoneType. Note that this * discards information; the new ZoneType will have meaningless * (empty) abbr, isdst, isstd, and isgmt flags; this is appropriate, * since ignoring these is how we do optimization (we have no use for * these in historical transitions). */ ZoneType::ZoneType(const SimplifiedZoneType& t) : rawoffset(t.rawoffset), dstoffset(t.dstoffset), abbr(-1), isdst(false), isstd(false), isgmt(false) {} /** * Optimize the type list to remove excess entries. The type list may * contain entries that are distinct only in terms of their dst, std, * or gmt flags. Since we don't care about those flags, we can reduce * the type list to a set of unique raw/dst offset pairs, and remap * the type indices in the transition list, which stores, for each * transition, a transition time and a type index. */ void ZoneInfo::optimizeTypeList() { // Assemble set of unique types; only those in the `transitions' // list, since there may be unused types in the `types' list // corresponding to transitions that have been trimmed (during // merging of final data). if (aliasTo >= 0) return; // Nothing to do for aliases if (!ICU44PLUS) { // This is the old logic which has a bug, which occasionally removes // the type before the first transition. The problem was fixed // by inserting the dummy transition indirectly. // If there are zero transitions and one type, then leave that as-is. if (transitions.size() == 0) { if (types.size() != 1) { cerr << "Error: transition count = 0, type count = " << types.size() << endl; } return; } set<SimplifiedZoneType> simpleset; for (vector<Transition>::const_iterator i=transitions.begin(); i!=transitions.end(); ++i) { assert(i->type < (int32_t)types.size()); simpleset.insert(types[i->type]); } // Map types to integer indices map<SimplifiedZoneType,int32_t> simplemap; int32_t n=0; for (set<SimplifiedZoneType>::const_iterator i=simpleset.begin(); i!=simpleset.end(); ++i) { simplemap[*i] = n++; } // Remap transitions for (vector<Transition>::iterator i=transitions.begin(); i!=transitions.end(); ++i) { assert(i->type < (int32_t)types.size()); ZoneType oldtype = types[i->type]; SimplifiedZoneType newtype(oldtype); assert(simplemap.find(newtype) != simplemap.end()); i->type = simplemap[newtype]; } // Replace type list types.clear(); copy(simpleset.begin(), simpleset.end(), back_inserter(types)); } else { if (types.size() > 1) { // Note: localtime uses the very first non-dst type as initial offsets. // If all types are DSTs, the very first type is treated as the initial offsets. // Decide a type used as the initial offsets. ICU put the type at index 0. ZoneType initialType = types[0]; for (vector<ZoneType>::const_iterator i=types.begin(); i!=types.end(); ++i) { if (i->dstoffset == 0) { initialType = *i; break; } } SimplifiedZoneType initialSimplifiedType(initialType); // create a set of unique types, but ignoring fields which we're not interested in set<SimplifiedZoneType> simpleset; simpleset.insert(initialSimplifiedType); for (vector<Transition>::const_iterator i=transitions.begin(); i!=transitions.end(); ++i) { assert(i->type < (int32_t)types.size()); simpleset.insert(types[i->type]); } // Map types to integer indices, however, keeping the first type at offset 0 map<SimplifiedZoneType,int32_t> simplemap; simplemap[initialSimplifiedType] = 0; int32_t n = 1; for (set<SimplifiedZoneType>::const_iterator i=simpleset.begin(); i!=simpleset.end(); ++i) { if (*i < initialSimplifiedType || initialSimplifiedType < *i) { simplemap[*i] = n++; } } // Remap transitions for (vector<Transition>::iterator i=transitions.begin(); i!=transitions.end(); ++i) { assert(i->type < (int32_t)types.size()); ZoneType oldtype = types[i->type]; SimplifiedZoneType newtype(oldtype); assert(simplemap.find(newtype) != simplemap.end()); i->type = simplemap[newtype]; } // Replace type list types.clear(); types.push_back(initialSimplifiedType); for (set<SimplifiedZoneType>::const_iterator i=simpleset.begin(); i!=simpleset.end(); ++i) { if (*i < initialSimplifiedType || initialSimplifiedType < *i) { types.push_back(*i); } } // Reiterating transitions to remove any transitions which // do not actually change the raw/dst offsets int32_t prevTypeIdx = 0; for (vector<Transition>::iterator i=transitions.begin(); i!=transitions.end();) { if (i->type == prevTypeIdx) { // this is not a time transition, probably just name change // e.g. America/Resolute after 2006 in 2010b transitions.erase(i); } else { prevTypeIdx = i->type; i++; } } } } } /** * Merge final zone data into this zone. */ void ZoneInfo::mergeFinalData(const FinalZone& fz) { int32_t year = fz.year; int64_t seconds = yearToSeconds(year); if (!ICU44PLUS) { if (seconds > HIGHEST_TIME32) { // Avoid transitions beyond signed 32bit max second. // This may result incorrect offset computation around // HIGHEST_TIME32. This is a limitation of ICU // before 4.4. seconds = HIGHEST_TIME32; } } vector<Transition>::iterator it = find_if(transitions.begin(), transitions.end(), bind2nd(ptr_fun(isAfter), seconds)); transitions.erase(it, transitions.end()); if (finalYear != -1) { throw invalid_argument("Final zone already merged in"); } finalYear = fz.year; finalOffset = fz.offset; finalRuleID = fz.ruleid; } /** * Merge the data from the given final zone into the core zone data by * calling the ZoneInfo member function mergeFinalData. */ void mergeOne(const string& zoneid, const FinalZone& fz) { if (ZONEINFO.find(zoneid) == ZONEINFO.end()) { throw invalid_argument("Unrecognized final zone ID"); } ZONEINFO[zoneid].mergeFinalData(fz); } /** * Visitor function that merges the final zone data into the main zone * data structures. It calls mergeOne for each final zone and its * list of aliases. */ void mergeFinalZone(const pair<string,FinalZone>& p) { const string& id = p.first; const FinalZone& fz = p.second; mergeOne(id, fz); } /** * Print this rule in resource bundle format to os. ID and enclosing * braces handled elsewhere. */ void FinalRule::print(ostream& os) const { // First print the rule part that enters DST; then the rule part // that exits it. int32_t whichpart = (part[0].offset != 0) ? 0 : 1; assert(part[whichpart].offset != 0); assert(part[1-whichpart].offset == 0); os << " "; for (int32_t i=0; i<2; ++i) { const FinalRulePart& p = part[whichpart]; whichpart = 1-whichpart; os << p.month << ", " << p.stz_dowim() << ", " << p.stz_dow() << ", " << p.time << ", " << p.timemode() << ", "; } os << part[whichpart].offset << endl; } int main(int argc, char *argv[]) { string rootpath, zonetab, version; bool validArgs = FALSE; if (argc == 4 || argc == 5) { validArgs = TRUE; rootpath = argv[1]; zonetab = argv[2]; version = argv[3]; if (argc == 5) { if (strcmp(argv[4], "--old") == 0) { ICU44PLUS = FALSE; TZ_RESOURCE_NAME = ICU_TZ_RESOURCE_OLD; } else { validArgs = FALSE; } } } if (!validArgs) { cout << "Usage: tz2icu <dir> <cmap> <tzver> [--old]" << endl << " <dir> path to zoneinfo file tree generated by" << endl << " ICU-patched version of zic" << endl << " <cmap> country map, from tzdata archive," << endl << " typically named \"zone.tab\"" << endl << " <tzver> version string, such as \"2003e\"" << endl << " --old generating resource format before ICU4.4" << endl; exit(1); } cout << "Olson data version: " << version << endl; cout << "ICU 4.4+ format: " << (ICU44PLUS ? "Yes" : "No") << endl; try { ifstream finals(ICU_ZONE_FILE); if (finals) { readFinalZonesAndRules(finals); cout << "Finished reading " << finalZones.size() << " final zones and " << finalRules.size() << " final rules from " ICU_ZONE_FILE << endl; } else { cerr << "Error: Unable to open " ICU_ZONE_FILE << endl; return 1; } } catch (const exception& error) { cerr << "Error: While reading " ICU_ZONE_FILE ": " << error.what() << endl; return 1; } try { // Recursively scan all files below the given path, accumulating // their data into ZONEINFO. All files must be TZif files. Any // failure along the way will result in a call to exit(1). scandir(rootpath); } catch (const exception& error) { cerr << "Error: While scanning " << rootpath << ": " << error.what() << endl; return 1; } cout << "Finished reading " << ZONEINFO.size() << " zoneinfo files [" << (ZONEINFO.begin())->first << ".." << (--ZONEINFO.end())->first << "]" << endl; try { for_each(finalZones.begin(), finalZones.end(), mergeFinalZone); } catch (const exception& error) { cerr << "Error: While merging final zone data: " << error.what() << endl; return 1; } // Process links (including ICU aliases). For each link set we have // a canonical ID (e.g., America/Los_Angeles) and a set of one or more // aliases (e.g., PST, PST8PDT, ...). // 1. Add all aliases as zone objects in ZONEINFO for (map<string,set<string> >::const_iterator i = links.begin(); i!=links.end(); ++i) { const string& olson = i->first; const set<string>& aliases = i->second; if (ZONEINFO.find(olson) == ZONEINFO.end()) { cerr << "Error: Invalid " << linkSource[olson] << " to non-existent \"" << olson << "\"" << endl; return 1; } for (set<string>::const_iterator j=aliases.begin(); j!=aliases.end(); ++j) { ZONEINFO[*j] = ZoneInfo(); } } // 2. Create a mapping from zones to index numbers 0..n-1. map<string,int32_t> zoneIDs; vector<string> zoneIDlist; int32_t z=0; for (ZoneMap::iterator i=ZONEINFO.begin(); i!=ZONEINFO.end(); ++i) { zoneIDs[i->first] = z++; zoneIDlist.push_back(i->first); } assert(z == (int32_t) ZONEINFO.size()); // 3. Merge aliases. Sometimes aliases link to other aliases; we // resolve these into simplest possible sets. map<string,set<string> > links2; map<string,string> reverse2; for (map<string,set<string> >::const_iterator i = links.begin(); i!=links.end(); ++i) { string olson = i->first; while (reverseLinks.find(olson) != reverseLinks.end()) { olson = reverseLinks[olson]; } for (set<string>::const_iterator j=i->second.begin(); j!=i->second.end(); ++j) { links2[olson].insert(*j); reverse2[*j] = olson; } } links = links2; reverseLinks = reverse2; if (false) { // Debugging: Emit link map for (map<string,set<string> >::const_iterator i = links.begin(); i!=links.end(); ++i) { cout << i->first << ": "; for (set<string>::const_iterator j=i->second.begin(); j!=i->second.end(); ++j) { cout << *j << ", "; } cout << endl; } } // 4. Update aliases for (map<string,set<string> >::const_iterator i = links.begin(); i!=links.end(); ++i) { const string& olson = i->first; const set<string>& aliases = i->second; ZONEINFO[olson].clearAliases(); ZONEINFO[olson].addAlias(zoneIDs[olson]); for (set<string>::const_iterator j=aliases.begin(); j!=aliases.end(); ++j) { assert(zoneIDs.find(olson) != zoneIDs.end()); assert(zoneIDs.find(*j) != zoneIDs.end()); assert(ZONEINFO.find(*j) != ZONEINFO.end()); ZONEINFO[*j].setAliasTo(zoneIDs[olson]); ZONEINFO[olson].addAlias(zoneIDs[*j]); } } // Once merging of final data is complete, we can optimize the type list for (ZoneMap::iterator i=ZONEINFO.begin(); i!=ZONEINFO.end(); ++i) { i->second.optimizeTypeList(); } // Create the country map map<string, string> icuRegions; // ICU's custom zone -> country override map<string, set<string> > countryMap; // country -> set of zones map<string, string> reverseCountryMap; // zone -> country try { // Read icuregions file to collect ICU's own zone-region mapping data. ifstream frg(ICU_REGIONS); if (frg) { string line; while (getline(frg, line)) { if (line[0] == '#') continue; string zone, country; istringstream is(line); is >> zone >> country; if (zone.size() == 0) continue; if (country.size() < 2) { cerr << "Error: Can't parse " << line << " in " << ICU_REGIONS << endl; return 1; } icuRegions[zone] = country; } } else { cout << "No custom region map [icuregions]" << endl; } } catch (const exception& error) { cerr << "Error: While reading " << ICU_REGIONS << ": " << error.what() << endl; return 1; } try { ifstream f(zonetab.c_str()); if (!f) { cerr << "Error: Unable to open " << zonetab << endl; return 1; } int32_t n = 0; string line; while (getline(f, line)) { string::size_type lb = line.find('#'); if (lb != string::npos) { line.resize(lb); // trim comments } string country, coord, zone; istringstream is(line); is >> country >> coord >> zone; if (country.size() == 0) continue; if (country.size() != 2 || zone.size() < 1) { cerr << "Error: Can't parse " << line << " in " << zonetab << endl; return 1; } if (ZONEINFO.find(zone) == ZONEINFO.end()) { cerr << "Error: Country maps to invalid zone " << zone << " in " << zonetab << endl; return 1; } if (icuRegions.find(zone) != icuRegions.end()) { // Custom override string customCountry = icuRegions[zone]; cout << "Region Mapping: custom override for " << zone << " " << country << " -> " << customCountry << endl; country = customCountry; } countryMap[country].insert(zone); reverseCountryMap[zone] = country; //cerr << (n+1) << ": " << country << " <=> " << zone << endl; ++n; } cout << "Finished reading " << n << " country entries from " << zonetab << endl; } catch (const exception& error) { cerr << "Error: While reading " << zonetab << ": " << error.what() << endl; return 1; } // Merge ICU's own zone-region mapping data for (map<string,string>::const_iterator i = icuRegions.begin(); i != icuRegions.end(); ++i) { const string& zid(i->first); if (reverseCountryMap.find(zid) != reverseCountryMap.end()) { continue; } cout << "Region Mapping: custom data zone=" << zid << ", region=" << i->second << endl; reverseCountryMap[zid] = i->second; countryMap[i->second].insert(zid); } // Merge ICU aliases into country map. Don't merge any alias // that already has a country map, since that doesn't make sense. // E.g. "Link Europe/Oslo Arctic/Longyearbyen" doesn't mean we // should cross-map the countries between these two zones. for (map<string,set<string> >::const_iterator i = links.begin(); i!=links.end(); ++i) { const string& olson(i->first); if (reverseCountryMap.find(olson) == reverseCountryMap.end()) { continue; } string c = reverseCountryMap[olson]; const set<string>& aliases(i->second); for (set<string>::const_iterator j=aliases.begin(); j != aliases.end(); ++j) { if (reverseCountryMap.find(*j) == reverseCountryMap.end()) { countryMap[c].insert(*j); reverseCountryMap[*j] = c; //cerr << "Aliased country: " << c << " <=> " << *j << endl; } } } // Create a pseudo-country containing all zones belonging to no country set<string> nocountry; for (ZoneMap::iterator i=ZONEINFO.begin(); i!=ZONEINFO.end(); ++i) { if (reverseCountryMap.find(i->first) == reverseCountryMap.end()) { nocountry.insert(i->first); } } countryMap[""] = nocountry; // Get local time & year for below time_t sec; time(&sec); struct tm* now = localtime(&sec); int32_t thisYear = now->tm_year + 1900; string filename = TZ_RESOURCE_NAME + ".txt"; // Write out a resource-bundle source file containing data for // all zones. ofstream file(filename.c_str()); if (file) { file << "//---------------------------------------------------------" << endl << "// Copyright (C) 2016 and later: Unicode, Inc. and others." << endl << "// License & terms of use: http://www.unicode.org/copyright.html#License" << endl << "//---------------------------------------------------------" << endl << "// Build tool: tz2icu" << endl << "// Build date: " << asctime(now) /* << endl -- asctime emits CR */ << "// tz database: ftp://ftp.iana.org/tz/" << endl << "// tz version: " << version << endl << "// ICU version: " << U_ICU_VERSION << endl << "//---------------------------------------------------------" << endl << "// >> !!! >> THIS IS A MACHINE-GENERATED FILE << !!! <<" << endl << "// >> !!! >>> DO NOT EDIT <<< !!! <<" << endl << "//---------------------------------------------------------" << endl << endl << TZ_RESOURCE_NAME << ":table(nofallback) {" << endl << " TZVersion { \"" << version << "\" }" << endl << " Zones:array { " << endl << ZONEINFO // Zones (the actual data) << " }" << endl; // Names correspond to the Zones list, used for binary searching. printStringList ( file, ZONEINFO ); // print the Names list // Final Rules are used if requested by the zone file << " Rules { " << endl; // Emit final rules int32_t frc = 0; for(map<string,FinalRule>::iterator i=finalRules.begin(); i!=finalRules.end(); ++i) { const string& id = i->first; const FinalRule& r = i->second; file << " " << id << ":intvector {" << endl; r.print(file); file << " } //_#" << frc++ << endl; } file << " }" << endl; // Emit country (region) map. if (ICU44PLUS) { file << " Regions:array {" << endl; int32_t zn = 0; for (ZoneMap::iterator i=ZONEINFO.begin(); i!=ZONEINFO.end(); ++i) { map<string, string>::iterator cit = reverseCountryMap.find(i->first); if (cit == reverseCountryMap.end()) { file << " \"001\","; } else { file << " \"" << cit->second << "\", "; } file << "//Z#" << zn++ << " " << i->first << endl; } file << " }" << endl; } else { file << " Regions { " << endl; int32_t rc = 0; for (map<string, set<string> >::const_iterator i=countryMap.begin(); i != countryMap.end(); ++i) { string country = i->first; const set<string>& zones(i->second); file << " "; if(country[0]==0) { file << "Default"; } file << country << ":intvector { "; bool first = true; for (set<string>::const_iterator j=zones.begin(); j != zones.end(); ++j) { if (!first) file << ", "; first = false; if (zoneIDs.find(*j) == zoneIDs.end()) { cerr << "Error: Nonexistent zone in country map: " << *j << endl; return 1; } file << zoneIDs[*j]; // emit the zone's index number } file << " } //R#" << rc++ << endl; } file << " }" << endl; } file << "}" << endl; } file.close(); if (file) { // recheck error bit cout << "Finished writing " << TZ_RESOURCE_NAME << ".txt" << endl; } else { cerr << "Error: Unable to open/write to " << TZ_RESOURCE_NAME << ".txt" << endl; return 1; } } //eof