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/*
 *  Copyright 2001-2015 Stephen Colebourne
 *
 *  Licensed 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,
 *  WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 *  See the License for the specific language governing permissions and
 *  limitations under the License.
 */
package io.prestosql.jdbc.$internal.joda.time.format;

import java.util.Arrays;
import java.util.Locale;

import io.prestosql.jdbc.$internal.joda.time.Chronology;
import io.prestosql.jdbc.$internal.joda.time.DateTimeField;
import io.prestosql.jdbc.$internal.joda.time.DateTimeFieldType;
import io.prestosql.jdbc.$internal.joda.time.DateTimeUtils;
import io.prestosql.jdbc.$internal.joda.time.DateTimeZone;
import io.prestosql.jdbc.$internal.joda.time.DurationField;
import io.prestosql.jdbc.$internal.joda.time.DurationFieldType;
import io.prestosql.jdbc.$internal.joda.time.IllegalFieldValueException;
import io.prestosql.jdbc.$internal.joda.time.IllegalInstantException;

/**
 * DateTimeParserBucket is an advanced class, intended mainly for parser
 * implementations. It can also be used during normal parsing operations to
 * capture more information about the parse.
 * 

* This class allows fields to be saved in any order, but be physically set in * a consistent order. This is useful for parsing against formats that allow * field values to contradict each other. *

* Field values are applied in an order where the "larger" fields are set * first, making their value less likely to stick. A field is larger than * another when it's range duration is longer. If both ranges are the same, * then the larger field has the longer duration. If it cannot be determined * which field is larger, then the fields are set in the order they were saved. *

* For example, these fields were saved in this order: dayOfWeek, monthOfYear, * dayOfMonth, dayOfYear. When computeMillis is called, the fields are set in * this order: monthOfYear, dayOfYear, dayOfMonth, dayOfWeek. *

* DateTimeParserBucket is mutable and not thread-safe. * * @author Brian S O'Neill * @author Fredrik Borgh * @since 1.0 */ public class DateTimeParserBucket { /** The chronology to use for parsing. */ private final Chronology iChrono; /** The initial millis. */ private final long iMillis; /** The locale to use for parsing. */ private final Locale iLocale; /** Used for parsing month/day without year. */ private final int iDefaultYear; /** The default zone from the constructor. */ private final DateTimeZone iDefaultZone; /** The default pivot year from the constructor. */ private final Integer iDefaultPivotYear; /** The parsed zone, initialised to formatter zone. */ private DateTimeZone iZone; /** The parsed offset. */ private Integer iOffset; /** Used for parsing two-digit years. */ private Integer iPivotYear; private SavedField[] iSavedFields; private int iSavedFieldsCount; private boolean iSavedFieldsShared; private Object iSavedState; /** * Constructs a bucket. * * @param instantLocal the initial millis from 1970-01-01T00:00:00, local time * @param chrono the chronology to use * @param locale the locale to use * @deprecated Use longer constructor */ @Deprecated public DateTimeParserBucket(long instantLocal, Chronology chrono, Locale locale) { this(instantLocal, chrono, locale, null, 2000); } /** * Constructs a bucket, with the option of specifying the pivot year for * two-digit year parsing. * * @param instantLocal the initial millis from 1970-01-01T00:00:00, local time * @param chrono the chronology to use * @param locale the locale to use * @param pivotYear the pivot year to use when parsing two-digit years * @since 1.1 * @deprecated Use longer constructor */ @Deprecated public DateTimeParserBucket(long instantLocal, Chronology chrono, Locale locale, Integer pivotYear) { this(instantLocal, chrono, locale, pivotYear, 2000); } /** * Constructs a bucket, with the option of specifying the pivot year for * two-digit year parsing. * * @param instantLocal the initial millis from 1970-01-01T00:00:00, local time * @param chrono the chronology to use * @param locale the locale to use * @param pivotYear the pivot year to use when parsing two-digit years * @param defaultYear the default year to use when parsing month-day * @since 2.0 */ public DateTimeParserBucket(long instantLocal, Chronology chrono, Locale locale, Integer pivotYear, int defaultYear) { super(); chrono = DateTimeUtils.getChronology(chrono); iMillis = instantLocal; iDefaultZone = chrono.getZone(); iChrono = chrono.withUTC(); iLocale = (locale == null ? Locale.getDefault() : locale); iDefaultYear = defaultYear; iDefaultPivotYear = pivotYear; // reset iZone = iDefaultZone; iPivotYear = iDefaultPivotYear; iSavedFields = new SavedField[8]; } //----------------------------------------------------------------------- /** * Resets the state back to that when the object was constructed. *

* This resets the state of the bucket, allowing a single bucket to be re-used * for many parses. The bucket must not be shared between threads. * * @since 2.4 */ public void reset() { iZone = iDefaultZone; iOffset = null; iPivotYear = iDefaultPivotYear; iSavedFieldsCount = 0; iSavedFieldsShared = false; iSavedState = null; } /** * Parses a datetime from the given text, returning the number of * milliseconds since the epoch, 1970-01-01T00:00:00Z. *

* This parses the text using the parser into this bucket. * The bucket is reset before parsing begins, allowing the bucket to be re-used. * The bucket must not be shared between threads. * * @param parser the parser to use, see {@link DateTimeFormatter#getParser()}, not null * @param text text to parse, not null * @return parsed value expressed in milliseconds since the epoch * @throws UnsupportedOperationException if parsing is not supported * @throws IllegalArgumentException if the text to parse is invalid * @since 2.4 */ public long parseMillis(DateTimeParser parser, CharSequence text) { reset(); return doParseMillis(DateTimeParserInternalParser.of(parser), text); } long doParseMillis(InternalParser parser, CharSequence text) { int newPos = parser.parseInto(this, text, 0); if (newPos >= 0) { if (newPos >= text.length()) { return computeMillis(true, text); } } else { newPos = ~newPos; } throw new IllegalArgumentException(FormatUtils.createErrorMessage(text.toString(), newPos)); } //----------------------------------------------------------------------- /** * Gets the chronology of the bucket, which will be a local (UTC) chronology. */ public Chronology getChronology() { return iChrono; } //----------------------------------------------------------------------- /** * Returns the locale to be used during parsing. * * @return the locale to use */ public Locale getLocale() { return iLocale; } //----------------------------------------------------------------------- /** * Returns the time zone used by computeMillis. */ public DateTimeZone getZone() { return iZone; } /** * Set a time zone to be used when computeMillis is called. */ public void setZone(DateTimeZone zone) { iSavedState = null; iZone = zone; } //----------------------------------------------------------------------- /** * Returns the time zone offset in milliseconds used by computeMillis. * @deprecated use Integer version */ @Deprecated public int getOffset() { return (iOffset != null ? iOffset : 0); } /** * Returns the time zone offset in milliseconds used by computeMillis. */ public Integer getOffsetInteger() { return iOffset; } /** * Set a time zone offset to be used when computeMillis is called. * @deprecated use Integer version */ @Deprecated public void setOffset(int offset) { iSavedState = null; iOffset = offset; } /** * Set a time zone offset to be used when computeMillis is called. */ public void setOffset(Integer offset) { iSavedState = null; iOffset = offset; } //----------------------------------------------------------------------- /** * Returns the default year used when information is incomplete. *

* This is used for two-digit years and when the largest parsed field is * months or days. *

* A null value for two-digit years means to use the value from DateTimeFormatterBuilder. * A null value for month/day only parsing will cause the default of 2000 to be used. * * @return Integer value of the pivot year, null if not set * @since 1.1 */ public Integer getPivotYear() { return iPivotYear; } /** * Sets the pivot year to use when parsing two digit years. *

* If the value is set to null, this will indicate that default * behaviour should be used. * * @param pivotYear the pivot year to use * @since 1.1 * @deprecated this method should never have been public */ @Deprecated public void setPivotYear(Integer pivotYear) { iPivotYear = pivotYear; } //----------------------------------------------------------------------- /** * Saves a datetime field value. * * @param field the field, whose chronology must match that of this bucket * @param value the value */ public void saveField(DateTimeField field, int value) { obtainSaveField().init(field, value); } /** * Saves a datetime field value. * * @param fieldType the field type * @param value the value */ public void saveField(DateTimeFieldType fieldType, int value) { obtainSaveField().init(fieldType.getField(iChrono), value); } /** * Saves a datetime field text value. * * @param fieldType the field type * @param text the text value * @param locale the locale to use */ public void saveField(DateTimeFieldType fieldType, String text, Locale locale) { obtainSaveField().init(fieldType.getField(iChrono), text, locale); } private SavedField obtainSaveField() { SavedField[] savedFields = iSavedFields; int savedFieldsCount = iSavedFieldsCount; if (savedFieldsCount == savedFields.length || iSavedFieldsShared) { // Expand capacity or merely copy if saved fields are shared. SavedField[] newArray = new SavedField [savedFieldsCount == savedFields.length ? savedFieldsCount * 2 : savedFields.length]; System.arraycopy(savedFields, 0, newArray, 0, savedFieldsCount); iSavedFields = savedFields = newArray; iSavedFieldsShared = false; } iSavedState = null; SavedField saved = savedFields[savedFieldsCount]; if (saved == null) { saved = savedFields[savedFieldsCount] = new SavedField(); } iSavedFieldsCount = savedFieldsCount + 1; return saved; } /** * Saves the state of this bucket, returning it in an opaque object. Call * restoreState to undo any changes that were made since the state was * saved. Calls to saveState may be nested. * * @return opaque saved state, which may be passed to restoreState */ public Object saveState() { if (iSavedState == null) { iSavedState = new SavedState(); } return iSavedState; } /** * Restores the state of this bucket from a previously saved state. The * state object passed into this method is not consumed, and it can be used * later to restore to that state again. * * @param savedState opaque saved state, returned from saveState * @return true state object is valid and state restored */ public boolean restoreState(Object savedState) { if (savedState instanceof SavedState) { if (((SavedState) savedState).restoreState(this)) { iSavedState = savedState; return true; } } return false; } /** * Computes the parsed datetime by setting the saved fields. * This method is idempotent, but it is not thread-safe. * * @return milliseconds since 1970-01-01T00:00:00Z * @throws IllegalArgumentException if any field is out of range */ public long computeMillis() { return computeMillis(false, (CharSequence) null); } /** * Computes the parsed datetime by setting the saved fields. * This method is idempotent, but it is not thread-safe. * * @param resetFields false by default, but when true, unsaved field values are cleared * @return milliseconds since 1970-01-01T00:00:00Z * @throws IllegalArgumentException if any field is out of range */ public long computeMillis(boolean resetFields) { return computeMillis(resetFields, (CharSequence) null); } /** * Computes the parsed datetime by setting the saved fields. * This method is idempotent, but it is not thread-safe. * * @param resetFields false by default, but when true, unsaved field values are cleared * @param text optional text being parsed, to be included in any error message * @return milliseconds since 1970-01-01T00:00:00Z * @throws IllegalArgumentException if any field is out of range * @since 1.3 */ public long computeMillis(boolean resetFields, String text) { return computeMillis(resetFields, (CharSequence) text); } /** * Computes the parsed datetime by setting the saved fields. * This method is idempotent, but it is not thread-safe. * * @param resetFields false by default, but when true, unsaved field values are cleared * @param text optional text being parsed, to be included in any error message * @return milliseconds since 1970-01-01T00:00:00Z * @throws IllegalArgumentException if any field is out of range * @since 2.4 */ public long computeMillis(boolean resetFields, CharSequence text) { SavedField[] savedFields = iSavedFields; int count = iSavedFieldsCount; if (iSavedFieldsShared) { // clone so that sort does not affect saved state iSavedFields = savedFields = (SavedField[])iSavedFields.clone(); iSavedFieldsShared = false; } sort(savedFields, count); if (count > 0) { // alter base year for parsing if first field is month or day DurationField months = DurationFieldType.months().getField(iChrono); DurationField days = DurationFieldType.days().getField(iChrono); DurationField first = savedFields[0].iField.getDurationField(); if (compareReverse(first, months) >= 0 && compareReverse(first, days) <= 0) { saveField(DateTimeFieldType.year(), iDefaultYear); return computeMillis(resetFields, text); } } long millis = iMillis; try { for (int i = 0; i < count; i++) { millis = savedFields[i].set(millis, resetFields); } if (resetFields) { for (int i = 0; i < count; i++) { if (!savedFields[i].iField.isLenient()) { millis = savedFields[i].set(millis, i == (count - 1)); } } } } catch (IllegalFieldValueException e) { if (text != null) { e.prependMessage("Cannot parse \"" + text + '"'); } throw e; } if (iOffset != null) { millis -= iOffset; } else if (iZone != null) { int offset = iZone.getOffsetFromLocal(millis); millis -= offset; if (offset != iZone.getOffset(millis)) { String message = "Illegal instant due to time zone offset transition (" + iZone + ')'; if (text != null) { message = "Cannot parse \"" + text + "\": " + message; } throw new IllegalInstantException(message); } } return millis; } /** * Sorts elements [0,high). Calling java.util.Arrays isn't always the right * choice since it always creates an internal copy of the array, even if it * doesn't need to. If the array slice is small enough, an insertion sort * is chosen instead, but it doesn't need a copy! *

* This method has a modified version of that insertion sort, except it * doesn't create an unnecessary array copy. If high is over 10, then * java.util.Arrays is called, which will perform a merge sort, which is * faster than insertion sort on large lists. *

* The end result is much greater performance when computeMillis is called. * Since the amount of saved fields is small, the insertion sort is a * better choice. Additional performance is gained since there is no extra * array allocation and copying. Also, the insertion sort here does not * perform any casting operations. The version in java.util.Arrays performs * casts within the insertion sort loop. */ private static void sort(SavedField[] array, int high) { if (high > 10) { Arrays.sort(array, 0, high); } else { for (int i=0; i0 && (array[j-1]).compareTo(array[j])>0; j--) { SavedField t = array[j]; array[j] = array[j-1]; array[j-1] = t; } } } } class SavedState { final DateTimeZone iZone; final Integer iOffset; final SavedField[] iSavedFields; final int iSavedFieldsCount; SavedState() { this.iZone = DateTimeParserBucket.this.iZone; this.iOffset = DateTimeParserBucket.this.iOffset; this.iSavedFields = DateTimeParserBucket.this.iSavedFields; this.iSavedFieldsCount = DateTimeParserBucket.this.iSavedFieldsCount; } boolean restoreState(DateTimeParserBucket enclosing) { if (enclosing != DateTimeParserBucket.this) { // block SavedState from a different bucket return false; } enclosing.iZone = this.iZone; enclosing.iOffset = this.iOffset; enclosing.iSavedFields = this.iSavedFields; if (this.iSavedFieldsCount < enclosing.iSavedFieldsCount) { // Since count is being restored to a lower count, the // potential exists for new saved fields to destroy data being // shared by another state. Set this flag such that the array // of saved fields is cloned prior to modification. enclosing.iSavedFieldsShared = true; } enclosing.iSavedFieldsCount = this.iSavedFieldsCount; return true; } } static class SavedField implements Comparable { DateTimeField iField; int iValue; String iText; Locale iLocale; SavedField() { } void init(DateTimeField field, int value) { iField = field; iValue = value; iText = null; iLocale = null; } void init(DateTimeField field, String text, Locale locale) { iField = field; iValue = 0; iText = text; iLocale = locale; } long set(long millis, boolean reset) { if (iText == null) { millis = iField.setExtended(millis, iValue); } else { millis = iField.set(millis, iText, iLocale); } if (reset) { millis = iField.roundFloor(millis); } return millis; } /** * The field with the longer range duration is ordered first, where * null is considered infinite. If the ranges match, then the field * with the longer duration is ordered first. */ public int compareTo(SavedField obj) { DateTimeField other = obj.iField; int result = compareReverse (iField.getRangeDurationField(), other.getRangeDurationField()); if (result != 0) { return result; } return compareReverse (iField.getDurationField(), other.getDurationField()); } } static int compareReverse(DurationField a, DurationField b) { if (a == null || !a.isSupported()) { if (b == null || !b.isSupported()) { return 0; } return -1; } if (b == null || !b.isSupported()) { return 1; } return -a.compareTo(b); } }





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