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JDK 11 java.base.jmod - Base Module
JDK 11 java.base.jmod is the JMOD file for JDK 11 Base module.
JDK 11 Base module compiled class files are stored in \fyicenter\jdk-11.0.1\jmods\java.base.jmod.
JDK 11 Base module compiled class files are also linked and stored in the \fyicenter\jdk-11.0.1\lib\modules JImage file.
JDK 11 Base module source code files are stored in \fyicenter\jdk-11.0.1\lib\src.zip\java.base.
You can click and view the content of each source code file in the list below.
✍: FYIcenter
⏎ java/nio/file/attribute/FileTime.java
/* * Copyright (c) 2009, 2013, Oracle and/or its affiliates. All rights reserved. * ORACLE PROPRIETARY/CONFIDENTIAL. Use is subject to license terms. * * * * * * * * * * * * * * * * * * * * */ package java.nio.file.attribute; import java.time.Instant; import java.time.LocalDateTime; import java.time.ZoneOffset; import java.util.Objects; import java.util.concurrent.TimeUnit; /** * Represents the value of a file's time stamp attribute. For example, it may * represent the time that the file was last * {@link BasicFileAttributes#lastModifiedTime() modified}, * {@link BasicFileAttributes#lastAccessTime() accessed}, * or {@link BasicFileAttributes#creationTime() created}. * * <p> Instances of this class are immutable. * * @since 1.7 * @see java.nio.file.Files#setLastModifiedTime * @see java.nio.file.Files#getLastModifiedTime */ public final class FileTime implements Comparable<FileTime> { /** * The unit of granularity to interpret the value. Null if * this {@code FileTime} is converted from an {@code Instant}, * the {@code value} and {@code unit} pair will not be used * in this scenario. */ private final TimeUnit unit; /** * The value since the epoch; can be negative. */ private final long value; /** * The value as Instant (created lazily, if not from an instant) */ private Instant instant; /** * The value return by toString (created lazily) */ private String valueAsString; /** * Initializes a new instance of this class. */ private FileTime(long value, TimeUnit unit, Instant instant) { this.value = value; this.unit = unit; this.instant = instant; } /** * Returns a {@code FileTime} representing a value at the given unit of * granularity. * * @param value * the value since the epoch (1970-01-01T00:00:00Z); can be * negative * @param unit * the unit of granularity to interpret the value * * @return a {@code FileTime} representing the given value */ public static FileTime from(long value, TimeUnit unit) { Objects.requireNonNull(unit, "unit"); return new FileTime(value, unit, null); } /** * Returns a {@code FileTime} representing the given value in milliseconds. * * @param value * the value, in milliseconds, since the epoch * (1970-01-01T00:00:00Z); can be negative * * @return a {@code FileTime} representing the given value */ public static FileTime fromMillis(long value) { return new FileTime(value, TimeUnit.MILLISECONDS, null); } /** * Returns a {@code FileTime} representing the same point of time value * on the time-line as the provided {@code Instant} object. * * @param instant * the instant to convert * @return a {@code FileTime} representing the same point on the time-line * as the provided instant * @since 1.8 */ public static FileTime from(Instant instant) { Objects.requireNonNull(instant, "instant"); return new FileTime(0, null, instant); } /** * Returns the value at the given unit of granularity. * * <p> Conversion from a coarser granularity that would numerically overflow * saturate to {@code Long.MIN_VALUE} if negative or {@code Long.MAX_VALUE} * if positive. * * @param unit * the unit of granularity for the return value * * @return value in the given unit of granularity, since the epoch * since the epoch (1970-01-01T00:00:00Z); can be negative */ public long to(TimeUnit unit) { Objects.requireNonNull(unit, "unit"); if (this.unit != null) { return unit.convert(this.value, this.unit); } else { long secs = unit.convert(instant.getEpochSecond(), TimeUnit.SECONDS); if (secs == Long.MIN_VALUE || secs == Long.MAX_VALUE) { return secs; } long nanos = unit.convert(instant.getNano(), TimeUnit.NANOSECONDS); long r = secs + nanos; // Math.addExact() variant if (((secs ^ r) & (nanos ^ r)) < 0) { return (secs < 0) ? Long.MIN_VALUE : Long.MAX_VALUE; } return r; } } /** * Returns the value in milliseconds. * * <p> Conversion from a coarser granularity that would numerically overflow * saturate to {@code Long.MIN_VALUE} if negative or {@code Long.MAX_VALUE} * if positive. * * @return the value in milliseconds, since the epoch (1970-01-01T00:00:00Z) */ public long toMillis() { if (unit != null) { return unit.toMillis(value); } else { long secs = instant.getEpochSecond(); int nanos = instant.getNano(); // Math.multiplyExact() variant long r = secs * 1000; long ax = Math.abs(secs); if (((ax | 1000) >>> 31 != 0)) { if ((r / 1000) != secs) { return (secs < 0) ? Long.MIN_VALUE : Long.MAX_VALUE; } } return r + nanos / 1000_000; } } /** * Time unit constants for conversion. */ private static final long HOURS_PER_DAY = 24L; private static final long MINUTES_PER_HOUR = 60L; private static final long SECONDS_PER_MINUTE = 60L; private static final long SECONDS_PER_HOUR = SECONDS_PER_MINUTE * MINUTES_PER_HOUR; private static final long SECONDS_PER_DAY = SECONDS_PER_HOUR * HOURS_PER_DAY; private static final long MILLIS_PER_SECOND = 1000L; private static final long MICROS_PER_SECOND = 1000_000L; private static final long NANOS_PER_SECOND = 1000_000_000L; private static final int NANOS_PER_MILLI = 1000_000; private static final int NANOS_PER_MICRO = 1000; // The epoch second of Instant.MIN. private static final long MIN_SECOND = -31557014167219200L; // The epoch second of Instant.MAX. private static final long MAX_SECOND = 31556889864403199L; /* * Scale d by m, checking for overflow. */ private static long scale(long d, long m, long over) { if (d > over) return Long.MAX_VALUE; if (d < -over) return Long.MIN_VALUE; return d * m; } /** * Converts this {@code FileTime} object to an {@code Instant}. * * <p> The conversion creates an {@code Instant} that represents the * same point on the time-line as this {@code FileTime}. * * <p> {@code FileTime} can store points on the time-line further in the * future and further in the past than {@code Instant}. Conversion * from such further time points saturates to {@link Instant#MIN} if * earlier than {@code Instant.MIN} or {@link Instant#MAX} if later * than {@code Instant.MAX}. * * @return an instant representing the same point on the time-line as * this {@code FileTime} object * @since 1.8 */ public Instant toInstant() { if (instant == null) { long secs = 0L; int nanos = 0; switch (unit) { case DAYS: secs = scale(value, SECONDS_PER_DAY, Long.MAX_VALUE/SECONDS_PER_DAY); break; case HOURS: secs = scale(value, SECONDS_PER_HOUR, Long.MAX_VALUE/SECONDS_PER_HOUR); break; case MINUTES: secs = scale(value, SECONDS_PER_MINUTE, Long.MAX_VALUE/SECONDS_PER_MINUTE); break; case SECONDS: secs = value; break; case MILLISECONDS: secs = Math.floorDiv(value, MILLIS_PER_SECOND); nanos = (int)Math.floorMod(value, MILLIS_PER_SECOND) * NANOS_PER_MILLI; break; case MICROSECONDS: secs = Math.floorDiv(value, MICROS_PER_SECOND); nanos = (int)Math.floorMod(value, MICROS_PER_SECOND) * NANOS_PER_MICRO; break; case NANOSECONDS: secs = Math.floorDiv(value, NANOS_PER_SECOND); nanos = (int)Math.floorMod(value, NANOS_PER_SECOND); break; default : throw new AssertionError("Unit not handled"); } if (secs <= MIN_SECOND) instant = Instant.MIN; else if (secs >= MAX_SECOND) instant = Instant.MAX; else instant = Instant.ofEpochSecond(secs, nanos); } return instant; } /** * Tests this {@code FileTime} for equality with the given object. * * <p> The result is {@code true} if and only if the argument is not {@code * null} and is a {@code FileTime} that represents the same time. This * method satisfies the general contract of the {@code Object.equals} method. * * @param obj * the object to compare with * * @return {@code true} if, and only if, the given object is a {@code * FileTime} that represents the same time */ @Override public boolean equals(Object obj) { return (obj instanceof FileTime) ? compareTo((FileTime)obj) == 0 : false; } /** * Computes a hash code for this file time. * * <p> The hash code is based upon the value represented, and satisfies the * general contract of the {@link Object#hashCode} method. * * @return the hash-code value */ @Override public int hashCode() { // hashcode of instant representation to satisfy contract with equals return toInstant().hashCode(); } private long toDays() { if (unit != null) { return unit.toDays(value); } else { return TimeUnit.SECONDS.toDays(toInstant().getEpochSecond()); } } private long toExcessNanos(long days) { if (unit != null) { return unit.toNanos(value - unit.convert(days, TimeUnit.DAYS)); } else { return TimeUnit.SECONDS.toNanos(toInstant().getEpochSecond() - TimeUnit.DAYS.toSeconds(days)); } } /** * Compares the value of two {@code FileTime} objects for order. * * @param other * the other {@code FileTime} to be compared * * @return {@code 0} if this {@code FileTime} is equal to {@code other}, a * value less than 0 if this {@code FileTime} represents a time * that is before {@code other}, and a value greater than 0 if this * {@code FileTime} represents a time that is after {@code other} */ @Override public int compareTo(FileTime other) { // same granularity if (unit != null && unit == other.unit) { return Long.compare(value, other.value); } else { // compare using instant representation when unit differs long secs = toInstant().getEpochSecond(); long secsOther = other.toInstant().getEpochSecond(); int cmp = Long.compare(secs, secsOther); if (cmp != 0) { return cmp; } cmp = Long.compare(toInstant().getNano(), other.toInstant().getNano()); if (cmp != 0) { return cmp; } if (secs != MAX_SECOND && secs != MIN_SECOND) { return 0; } // if both this and other's Instant reps are MIN/MAX, // use daysSinceEpoch and nanosOfDays, which will not // saturate during calculation. long days = toDays(); long daysOther = other.toDays(); if (days == daysOther) { return Long.compare(toExcessNanos(days), other.toExcessNanos(daysOther)); } return Long.compare(days, daysOther); } } // days in a 400 year cycle = 146097 // days in a 10,000 year cycle = 146097 * 25 // seconds per day = 86400 private static final long DAYS_PER_10000_YEARS = 146097L * 25L; private static final long SECONDS_PER_10000_YEARS = 146097L * 25L * 86400L; private static final long SECONDS_0000_TO_1970 = ((146097L * 5L) - (30L * 365L + 7L)) * 86400L; // append year/month/day/hour/minute/second/nano with width and 0 padding private StringBuilder append(StringBuilder sb, int w, int d) { while (w > 0) { sb.append((char)(d/w + '0')); d = d % w; w /= 10; } return sb; } /** * Returns the string representation of this {@code FileTime}. The string * is returned in the <a * href="http://www.w3.org/TR/NOTE-datetime">ISO 8601</a> format: * <pre> * YYYY-MM-DDThh:mm:ss[.s+]Z * </pre> * where "{@code [.s+]}" represents a dot followed by one of more digits * for the decimal fraction of a second. It is only present when the decimal * fraction of a second is not zero. For example, {@code * FileTime.fromMillis(1234567890000L).toString()} yields {@code * "2009-02-13T23:31:30Z"}, and {@code FileTime.fromMillis(1234567890123L).toString()} * yields {@code "2009-02-13T23:31:30.123Z"}. * * <p> A {@code FileTime} is primarily intended to represent the value of a * file's time stamp. Where used to represent <i>extreme values</i>, where * the year is less than "{@code 0001}" or greater than "{@code 9999}" then * this method deviates from ISO 8601 in the same manner as the * <a href="http://www.w3.org/TR/xmlschema-2/#deviantformats">XML Schema * language</a>. That is, the year may be expanded to more than four digits * and may be negative-signed. If more than four digits then leading zeros * are not present. The year before "{@code 0001}" is "{@code -0001}". * * @return the string representation of this file time */ @Override public String toString() { if (valueAsString == null) { long secs = 0L; int nanos = 0; if (instant == null && unit.compareTo(TimeUnit.SECONDS) >= 0) { secs = unit.toSeconds(value); } else { secs = toInstant().getEpochSecond(); nanos = toInstant().getNano(); } LocalDateTime ldt; int year = 0; if (secs >= -SECONDS_0000_TO_1970) { // current era long zeroSecs = secs - SECONDS_PER_10000_YEARS + SECONDS_0000_TO_1970; long hi = Math.floorDiv(zeroSecs, SECONDS_PER_10000_YEARS) + 1; long lo = Math.floorMod(zeroSecs, SECONDS_PER_10000_YEARS); ldt = LocalDateTime.ofEpochSecond(lo - SECONDS_0000_TO_1970, nanos, ZoneOffset.UTC); year = ldt.getYear() + (int)hi * 10000; } else { // before current era long zeroSecs = secs + SECONDS_0000_TO_1970; long hi = zeroSecs / SECONDS_PER_10000_YEARS; long lo = zeroSecs % SECONDS_PER_10000_YEARS; ldt = LocalDateTime.ofEpochSecond(lo - SECONDS_0000_TO_1970, nanos, ZoneOffset.UTC); year = ldt.getYear() + (int)hi * 10000; } if (year <= 0) { year = year - 1; } int fraction = ldt.getNano(); StringBuilder sb = new StringBuilder(64); sb.append(year < 0 ? "-" : ""); year = Math.abs(year); if (year < 10000) { append(sb, 1000, Math.abs(year)); } else { sb.append(String.valueOf(year)); } sb.append('-'); append(sb, 10, ldt.getMonthValue()); sb.append('-'); append(sb, 10, ldt.getDayOfMonth()); sb.append('T'); append(sb, 10, ldt.getHour()); sb.append(':'); append(sb, 10, ldt.getMinute()); sb.append(':'); append(sb, 10, ldt.getSecond()); if (fraction != 0) { sb.append('.'); // adding leading zeros and stripping any trailing zeros int w = 100_000_000; while (fraction % 10 == 0) { fraction /= 10; w /= 10; } append(sb, w, fraction); } sb.append('Z'); valueAsString = sb.toString(); } return valueAsString; } }
⏎ java/nio/file/attribute/FileTime.java
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File name: java.base-11.0.1-src.zip File size: 8740354 bytes Release date: 2018-11-04 Download
2020-05-29, 242591👍, 0💬
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