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/*
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.
 * The ASF licenses this file to you under the Apache License, Version 2.0
 * (the "License"); you may not use this file except in compliance with
 * the License.  You may obtain a copy of the License at
 *
 * http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
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package org.apache.calcite.avatica.util;

import java.text.NumberFormat;
import java.text.ParsePosition;
import java.text.SimpleDateFormat;
import java.util.Calendar;
import java.util.TimeZone;

/**
 * Utility functions for datetime types: date, time, timestamp.
 *
 * 

Used by the JDBC driver. * *

TODO: review methods for performance. Due to allocations required, it may * be preferable to introduce a "formatter" with the required state. */ public class DateTimeUtils { /** The julian date of the epoch, 1970-01-01. */ public static final int EPOCH_JULIAN = 2440588; private DateTimeUtils() {} //~ Static fields/initializers --------------------------------------------- /** The SimpleDateFormat string for ISO dates, "yyyy-MM-dd". */ public static final String DATE_FORMAT_STRING = "yyyy-MM-dd"; /** The SimpleDateFormat string for ISO times, "HH:mm:ss". */ public static final String TIME_FORMAT_STRING = "HH:mm:ss"; /** The SimpleDateFormat string for ISO timestamps, "yyyy-MM-dd HH:mm:ss". */ public static final String TIMESTAMP_FORMAT_STRING = DATE_FORMAT_STRING + " " + TIME_FORMAT_STRING; /** The GMT time zone. */ public static final TimeZone GMT_ZONE = TimeZone.getTimeZone("GMT"); /** The Java default time zone. */ public static final TimeZone DEFAULT_ZONE = TimeZone.getDefault(); /** * The number of milliseconds in a second. */ public static final long MILLIS_PER_SECOND = 1000L; /** * The number of milliseconds in a minute. */ public static final long MILLIS_PER_MINUTE = 60000L; /** * The number of milliseconds in an hour. */ public static final long MILLIS_PER_HOUR = 3600000L; // = 60 * 60 * 1000 /** * The number of milliseconds in a day. * *

This is the modulo 'mask' used when converting * TIMESTAMP values to DATE and TIME values. */ public static final long MILLIS_PER_DAY = 86400000; // = 24 * 60 * 60 * 1000 /** * Calendar set to the epoch (1970-01-01 00:00:00 UTC). Useful for * initializing other values. Calendars are not immutable, so be careful not * to screw up this object for everyone else. */ public static final Calendar ZERO_CALENDAR; static { ZERO_CALENDAR = Calendar.getInstance(DateTimeUtils.GMT_ZONE); ZERO_CALENDAR.setTimeInMillis(0); } /** * Calendar set to local time. */ private static final Calendar LOCAL_CALENDAR = Calendar.getInstance(); //~ Methods ---------------------------------------------------------------- /** * Parses a string using {@link SimpleDateFormat} and a given pattern. This * method parses a string at the specified parse position and if successful, * updates the parse position to the index after the last character used. * The parsing is strict and requires months to be less than 12, days to be * less than 31, etc. * * @param s string to be parsed * @param pattern {@link SimpleDateFormat} pattern * @param tz time zone in which to interpret string. Defaults to the Java * default time zone * @param pp position to start parsing from * @return a Calendar initialized with the parsed value, or null if parsing * failed. If returned, the Calendar is configured to the GMT time zone. * @pre pattern != null */ private static Calendar parseDateFormat( String s, String pattern, TimeZone tz, ParsePosition pp) { assert pattern != null; SimpleDateFormat df = new SimpleDateFormat(pattern); if (tz == null) { tz = DEFAULT_ZONE; } Calendar ret = Calendar.getInstance(tz); df.setCalendar(ret); df.setLenient(false); java.util.Date d = df.parse(s, pp); if (null == d) { return null; } ret.setTime(d); ret.setTimeZone(GMT_ZONE); return ret; } /** * Parses a string using {@link SimpleDateFormat} and a given pattern. The * entire string must match the pattern specified. * * @param s string to be parsed * @param pattern {@link SimpleDateFormat} pattern * @param tz time zone in which to interpret string. Defaults to the Java * default time zone * @return a Calendar initialized with the parsed value, or null if parsing * failed. If returned, the Calendar is configured to the GMT time zone. */ public static Calendar parseDateFormat( String s, String pattern, TimeZone tz) { assert pattern != null; ParsePosition pp = new ParsePosition(0); Calendar ret = parseDateFormat(s, pattern, tz, pp); if (pp.getIndex() != s.length()) { // Didn't consume entire string - not good return null; } return ret; } /** * Parses a string using {@link SimpleDateFormat} and a given pattern, and * if present, parses a fractional seconds component. The fractional seconds * component must begin with a decimal point ('.') followed by numeric * digits. The precision is rounded to a maximum of 3 digits of fractional * seconds precision (to obtain milliseconds). * * @param s string to be parsed * @param pattern {@link SimpleDateFormat} pattern * @param tz time zone in which to interpret string. Defaults to the * local time zone * @return a {@link DateTimeUtils.PrecisionTime PrecisionTime} initialized * with the parsed value, or null if parsing failed. The PrecisionTime * contains a GMT Calendar and a precision. */ public static PrecisionTime parsePrecisionDateTimeLiteral( String s, String pattern, TimeZone tz) { assert pattern != null; ParsePosition pp = new ParsePosition(0); Calendar cal = parseDateFormat(s, pattern, tz, pp); if (cal == null) { return null; // Invalid date/time format } // Note: the Java SimpleDateFormat 'S' treats any number after // the decimal as milliseconds. That means 12:00:00.9 has 9 // milliseconds and 12:00:00.9999 has 9999 milliseconds. int p = 0; if (pp.getIndex() < s.length()) { // Check to see if rest is decimal portion if (s.charAt(pp.getIndex()) != '.') { return null; } // Skip decimal sign pp.setIndex(pp.getIndex() + 1); // Parse decimal portion if (pp.getIndex() < s.length()) { String secFraction = s.substring(pp.getIndex()); if (!secFraction.matches("\\d+")) { return null; } NumberFormat nf = NumberFormat.getIntegerInstance(); Number num = nf.parse(s, pp); if ((num == null) || (pp.getIndex() != s.length())) { // Invalid decimal portion return null; } // Determine precision - only support prec 3 or lower // (milliseconds) Higher precisions are quietly rounded away p = Math.min( 3, secFraction.length()); // Calculate milliseconds int ms = (int) Math.round( num.longValue() * Math.pow(10, 3 - secFraction.length())); cal.add(Calendar.MILLISECOND, ms); } } assert pp.getIndex() == s.length(); PrecisionTime ret = new PrecisionTime(cal, p); return ret; } /** * Gets the active time zone based on a Calendar argument */ public static TimeZone getTimeZone(Calendar cal) { if (cal == null) { return DEFAULT_ZONE; } return cal.getTimeZone(); } /** * Checks if the date/time format is valid * * @param pattern {@link SimpleDateFormat} pattern * @throws IllegalArgumentException if the given pattern is invalid */ public static void checkDateFormat(String pattern) { new SimpleDateFormat(pattern); } /** * Creates a new date formatter with Farrago specific options. Farrago * parsing is strict and does not allow values such as day 0, month 13, etc. * * @param format {@link SimpleDateFormat} pattern */ public static SimpleDateFormat newDateFormat(String format) { SimpleDateFormat sdf = new SimpleDateFormat(format); sdf.setLenient(false); return sdf; } /** Helper for CAST({timestamp} AS VARCHAR(n)). */ public static String unixTimestampToString(long timestamp) { final StringBuilder buf = new StringBuilder(17); int date = (int) (timestamp / MILLIS_PER_DAY); int time = (int) (timestamp % MILLIS_PER_DAY); if (time < 0) { --date; time += MILLIS_PER_DAY; } unixDateToString(buf, date); buf.append(' '); unixTimeToString(buf, time); return buf.toString(); } /** Helper for CAST({timestamp} AS VARCHAR(n)). */ public static String unixTimeToString(int time) { final StringBuilder buf = new StringBuilder(8); unixTimeToString(buf, time); return buf.toString(); } private static void unixTimeToString(StringBuilder buf, int time) { int h = time / 3600000; int time2 = time % 3600000; int m = time2 / 60000; int time3 = time2 % 60000; int s = time3 / 1000; int ms = time3 % 1000; int2(buf, h); buf.append(':'); int2(buf, m); buf.append(':'); int2(buf, s); } private static void int2(StringBuilder buf, int i) { buf.append((char) ('0' + (i / 10) % 10)); buf.append((char) ('0' + i % 10)); } private static void int4(StringBuilder buf, int i) { buf.append((char) ('0' + (i / 1000) % 10)); buf.append((char) ('0' + (i / 100) % 10)); buf.append((char) ('0' + (i / 10) % 10)); buf.append((char) ('0' + i % 10)); } /** Helper for CAST({date} AS VARCHAR(n)). */ public static String unixDateToString(int date) { final StringBuilder buf = new StringBuilder(10); unixDateToString(buf, date); return buf.toString(); } private static void unixDateToString(StringBuilder buf, int date) { julianToString(buf, date + EPOCH_JULIAN); } private static void julianToString(StringBuilder buf, int julian) { // this shifts the epoch back to astronomical year -4800 instead of the // start of the Christian era in year AD 1 of the proleptic Gregorian // calendar. int j = julian + 32044; int g = j / 146097; int dg = j % 146097; int c = (dg / 36524 + 1) * 3 / 4; int dc = dg - c * 36524; int b = dc / 1461; int db = dc % 1461; int a = (db / 365 + 1) * 3 / 4; int da = db - a * 365; // integer number of full years elapsed since March 1, 4801 BC int y = g * 400 + c * 100 + b * 4 + a; // integer number of full months elapsed since the last March 1 int m = (da * 5 + 308) / 153 - 2; // number of days elapsed since day 1 of the month int d = da - (m + 4) * 153 / 5 + 122; int year = y - 4800 + (m + 2) / 12; int month = (m + 2) % 12 + 1; int day = d + 1; int4(buf, year); buf.append('-'); int2(buf, month); buf.append('-'); int2(buf, day); } public static String intervalYearMonthToString(int v, TimeUnitRange range) { final StringBuilder buf = new StringBuilder(); if (v >= 0) { buf.append('+'); } else { buf.append('-'); v = -v; } final int y; final int m; switch (range) { case YEAR: v = roundUp(v, 12); y = v / 12; buf.append(y); break; case YEAR_TO_MONTH: y = v / 12; buf.append(y); buf.append('-'); m = v % 12; number(buf, m, 2); break; case MONTH: m = v; buf.append(m); break; default: throw new AssertionError(range); } return buf.toString(); } public static StringBuilder number(StringBuilder buf, int v, int n) { for (int k = digitCount(v); k < n; k++) { buf.append('0'); } return buf.append(v); } public static int digitCount(int v) { for (int n = 1;; n++) { v /= 10; if (v == 0) { return n; } } } private static int roundUp(int dividend, int divisor) { int remainder = dividend % divisor; dividend -= remainder; if (remainder * 2 > divisor) { dividend += divisor; } return dividend; } /** Cheap, unsafe, long power. power(2, 3) returns 8. */ public static long powerX(long a, long b) { long x = 1; while (b > 0) { x *= a; --b; } return x; } public static String intervalDayTimeToString(long v, TimeUnitRange range, int scale) { final StringBuilder buf = new StringBuilder(); if (v >= 0) { buf.append('+'); } else { buf.append('-'); v = -v; } final long ms; final long s; final long m; final long h; final long d; switch (range) { case DAY_TO_SECOND: v = roundUp(v, powerX(10, 3 - scale)); ms = v % 1000; v /= 1000; s = v % 60; v /= 60; m = v % 60; v /= 60; h = v % 24; v /= 24; d = v; buf.append((int) d); buf.append(' '); number(buf, (int) h, 2); buf.append(':'); number(buf, (int) m, 2); buf.append(':'); number(buf, (int) s, 2); fraction(buf, scale, ms); break; case DAY_TO_MINUTE: v = roundUp(v, 1000 * 60); v /= 1000; v /= 60; m = v % 60; v /= 60; h = v % 24; v /= 24; d = v; buf.append((int) d); buf.append(' '); number(buf, (int) h, 2); buf.append(':'); number(buf, (int) m, 2); break; case DAY_TO_HOUR: v = roundUp(v, 1000 * 60 * 60); v /= 1000; v /= 60; v /= 60; h = v % 24; v /= 24; d = v; buf.append((int) d); buf.append(' '); number(buf, (int) h, 2); break; case DAY: v = roundUp(v, 1000 * 60 * 60 * 24); d = v / (1000 * 60 * 60 * 24); buf.append((int) d); break; case HOUR: v = roundUp(v, 1000 * 60 * 60); v /= 1000; v /= 60; v /= 60; h = v; buf.append((int) h); break; case HOUR_TO_MINUTE: v = roundUp(v, 1000 * 60); v /= 1000; v /= 60; m = v % 60; v /= 60; h = v; buf.append((int) h); buf.append(':'); number(buf, (int) m, 2); break; case HOUR_TO_SECOND: v = roundUp(v, powerX(10, 3 - scale)); ms = v % 1000; v /= 1000; s = v % 60; v /= 60; m = v % 60; v /= 60; h = v; buf.append((int) h); buf.append(':'); number(buf, (int) m, 2); buf.append(':'); number(buf, (int) s, 2); fraction(buf, scale, ms); break; case MINUTE_TO_SECOND: v = roundUp(v, powerX(10, 3 - scale)); ms = v % 1000; v /= 1000; s = v % 60; v /= 60; m = v; buf.append((int) m); buf.append(':'); number(buf, (int) s, 2); fraction(buf, scale, ms); break; case MINUTE: v = roundUp(v, 1000 * 60); v /= 1000; v /= 60; m = v; buf.append((int) m); break; case SECOND: v = roundUp(v, powerX(10, 3 - scale)); ms = v % 1000; v /= 1000; s = v; buf.append((int) s); fraction(buf, scale, ms); break; default: throw new AssertionError(range); } return buf.toString(); } /** * Rounds a dividend to the nearest divisor. * For example roundUp(31, 10) yields 30; roundUp(37, 10) yields 40. * @param dividend Number to be divided * @param divisor Number to divide by * @return Rounded dividend */ private static long roundUp(long dividend, long divisor) { long remainder = dividend % divisor; dividend -= remainder; if (remainder * 2 > divisor) { dividend += divisor; } return dividend; } private static void fraction(StringBuilder buf, int scale, long ms) { if (scale > 0) { buf.append('.'); long v1 = scale == 3 ? ms : scale == 2 ? ms / 10 : scale == 1 ? ms / 100 : 0; number(buf, (int) v1, scale); } } public static int dateStringToUnixDate(String s) { int hyphen1 = s.indexOf('-'); int y; int m; int d; if (hyphen1 < 0) { y = Integer.parseInt(s.trim()); m = 1; d = 1; } else { y = Integer.parseInt(s.substring(0, hyphen1).trim()); final int hyphen2 = s.indexOf('-', hyphen1 + 1); if (hyphen2 < 0) { m = Integer.parseInt(s.substring(hyphen1 + 1).trim()); d = 1; } else { m = Integer.parseInt(s.substring(hyphen1 + 1, hyphen2).trim()); d = Integer.parseInt(s.substring(hyphen2 + 1).trim()); } } return ymdToUnixDate(y, m, d); } public static int timeStringToUnixDate(String v) { return timeStringToUnixDate(v, 0); } public static int timeStringToUnixDate(String v, int start) { final int colon1 = v.indexOf(':', start); int hour; int minute; int second; int milli; if (colon1 < 0) { hour = Integer.parseInt(v.trim()); minute = 1; second = 1; milli = 0; } else { hour = Integer.parseInt(v.substring(start, colon1).trim()); final int colon2 = v.indexOf(':', colon1 + 1); if (colon2 < 0) { minute = Integer.parseInt(v.substring(colon1 + 1).trim()); second = 1; milli = 0; } else { minute = Integer.parseInt(v.substring(colon1 + 1, colon2).trim()); int dot = v.indexOf('.', colon2); if (dot < 0) { second = Integer.parseInt(v.substring(colon2 + 1).trim()); milli = 0; } else { second = Integer.parseInt(v.substring(colon2 + 1, dot).trim()); milli = Integer.parseInt(v.substring(dot + 1).trim()); } } } return hour * (int) MILLIS_PER_HOUR + minute * (int) MILLIS_PER_MINUTE + second * (int) MILLIS_PER_SECOND + milli; } public static long timestampStringToUnixDate(String s) { final long d; final long t; s = s.trim(); int space = s.indexOf(' '); if (space >= 0) { d = dateStringToUnixDate(s.substring(0, space)); t = timeStringToUnixDate(s, space + 1); } else { d = dateStringToUnixDate(s); t = 0; } return d * MILLIS_PER_DAY + t; } public static long unixDateExtract(TimeUnitRange range, long date) { return julianExtract(range, (int) date + EPOCH_JULIAN); } private static int julianExtract(TimeUnitRange range, int julian) { // this shifts the epoch back to astronomical year -4800 instead of the // start of the Christian era in year AD 1 of the proleptic Gregorian // calendar. int j = julian + 32044; int g = j / 146097; int dg = j % 146097; int c = (dg / 36524 + 1) * 3 / 4; int dc = dg - c * 36524; int b = dc / 1461; int db = dc % 1461; int a = (db / 365 + 1) * 3 / 4; int da = db - a * 365; // integer number of full years elapsed since March 1, 4801 BC int y = g * 400 + c * 100 + b * 4 + a; // integer number of full months elapsed since the last March 1 int m = (da * 5 + 308) / 153 - 2; // number of days elapsed since day 1 of the month int d = da - (m + 4) * 153 / 5 + 122; int year = y - 4800 + (m + 2) / 12; int month = (m + 2) % 12 + 1; int day = d + 1; switch (range) { case YEAR: return year; case MONTH: return month; case DAY: return day; default: throw new AssertionError(range); } } /** Resets to zero the "time" part of a timestamp. */ public static long resetTime(long timestamp) { int date = (int) (timestamp / MILLIS_PER_DAY); return (long) date * MILLIS_PER_DAY; } /** Resets to epoch (1970-01-01) the "date" part of a timestamp. */ public static long resetDate(long timestamp) { return floorMod(timestamp, MILLIS_PER_DAY); } public static long unixTimestampFloor(TimeUnitRange range, long timestamp) { int date = (int) (timestamp / MILLIS_PER_DAY); final int f = julianDateFloor(range, date + EPOCH_JULIAN, true); return (long) f * MILLIS_PER_DAY; } public static long unixDateFloor(TimeUnitRange range, long date) { return julianDateFloor(range, (int) date + EPOCH_JULIAN, true); } public static long unixTimestampCeil(TimeUnitRange range, long timestamp) { int date = (int) (timestamp / MILLIS_PER_DAY); final int f = julianDateFloor(range, date + EPOCH_JULIAN, false); return (long) f * MILLIS_PER_DAY; } public static long unixDateCeil(TimeUnitRange range, long date) { return julianDateFloor(range, (int) date + EPOCH_JULIAN, true); } private static int julianDateFloor(TimeUnitRange range, int julian, boolean floor) { // this shifts the epoch back to astronomical year -4800 instead of the // start of the Christian era in year AD 1 of the proleptic Gregorian // calendar. int j = julian + 32044; int g = j / 146097; int dg = j % 146097; int c = (dg / 36524 + 1) * 3 / 4; int dc = dg - c * 36524; int b = dc / 1461; int db = dc % 1461; int a = (db / 365 + 1) * 3 / 4; int da = db - a * 365; // integer number of full years elapsed since March 1, 4801 BC int y = g * 400 + c * 100 + b * 4 + a; // integer number of full months elapsed since the last March 1 int m = (da * 5 + 308) / 153 - 2; // number of days elapsed since day 1 of the month int d = da - (m + 4) * 153 / 5 + 122; int year = y - 4800 + (m + 2) / 12; int month = (m + 2) % 12 + 1; int day = d + 1; switch (range) { case YEAR: if (!floor && (month > 1 || day > 1)) { ++year; } return ymdToUnixDate(year, 1, 1); case MONTH: if (!floor && day > 1) { ++month; } return ymdToUnixDate(year, month, 1); default: throw new AssertionError(range); } } public static int ymdToUnixDate(int year, int month, int day) { final int julian = ymdToJulian(year, month, day); return julian - EPOCH_JULIAN; } public static int ymdToJulian(int year, int month, int day) { int a = (14 - month) / 12; int y = year + 4800 - a; int m = month + 12 * a - 3; int j = day + (153 * m + 2) / 5 + 365 * y + y / 4 - y / 100 + y / 400 - 32045; if (j < 2299161) { j = day + (153 * m + 2) / 5 + 365 * y + y / 4 - 32083; } return j; } public static long unixTimestamp(int year, int month, int day, int hour, int minute, int second) { final int date = ymdToUnixDate(year, month, day); return (long) date * MILLIS_PER_DAY + (long) hour * MILLIS_PER_HOUR + (long) minute * MILLIS_PER_MINUTE + (long) second * MILLIS_PER_SECOND; } /** Divide, rounding towards negative infinity. */ public static long floorDiv(long x, long y) { long r = x / y; // if the signs are different and modulo not zero, round down if ((x ^ y) < 0 && (r * y != x)) { r--; } return r; } /** Modulo, always returning a non-negative result. */ public static long floorMod(long x, long y) { return x - floorDiv(x, y) * y; } //~ Inner Classes ---------------------------------------------------------- /** * Helper class for {@link DateTimeUtils#parsePrecisionDateTimeLiteral} */ public static class PrecisionTime { private final Calendar cal; private final int precision; public PrecisionTime(Calendar cal, int precision) { this.cal = cal; this.precision = precision; } public Calendar getCalendar() { return cal; } public int getPrecision() { return precision; } } } // End DateTimeUtils.java





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