org.apache.inlong.sort.filesystem.shaded.software.amazon.ion.IonReader Maven / Gradle / Ivy
/*
* Copyright 2008-2016 Amazon.com, Inc. or its affiliates. All Rights Reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License").
* You may not use this file except in compliance with the License.
* A copy of the License is located at:
*
* http://aws.amazon.com/apache2.0/
*
* or in the "license" file accompanying this file. This file 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 software.amazon.ion;
import java.io.Closeable;
import java.io.IOException;
import java.math.BigDecimal;
import java.math.BigInteger;
import java.util.Date;
import java.util.Iterator;
import software.amazon.ion.facet.Faceted;
/* One design goal is for the readers and writers to be independent of an
* IonSystem or ValueFactory and thus independent of particular implementations
* of the DOM.
*
* The issue is that one needs a ValueFactory in order to construct the tree.
* So one either needs to pass a ValueFactory / IonSystem to the reader, or
* pass the reader to the system. I decided that the dependencies were better
* the latter way. So we have IonSystem.newValue(IonReader) instead of
* IonReader.nextValue(IonSystem).
*/
/**
* Provides stream-based access to Ion data independent of its underlying
* representation (text, binary, or {@link IonValue} tree).
*
* WARNING: This interface should not be implemented or extended by
* code outside of this library.
* We still have some work to do before this interface is stable.
* See issue amznlabs/ion-java#11
*
* An {@code IonReader} has a "cursor" tracking the current value on
* which the reader is positioned. Generally, newly created readers are not
* positioned on any value. To begin traversing the Ion data, one would use
* {@link #next()} to advance the cursor onto the first value (or learn there isn't
* one). Once positioned, the current value's data can be accessed with the
* {@code *Value()} methods.
*
* When the current value is a container, calling {@link #next()} moves the
* cursor to the next sibling of the container, at the same depth,
* skipping over any children the container may have.
* To read the children, call {@link #stepIn()},
* then {@link #next()} to position onto the first child value (or learn there
* isn't one). Calling {@link #stepOut()} skips over any remaining children
* and moves the cursor just beyond the container; call {@link #next()} to
* move the cursor to the following value.
*
* In general, method names are intended to parallel similar methods in the
* {@link IonValue} hierarchy. For example, to get the text of a symbol one
* would use {@link #stringValue()}, mirroring {@link IonSymbol#stringValue()}.
*
*
Exception Handling
* {@code IonReader} is a generic interface for traversing Ion data, and it's
* not possible to fully specify the set of exceptions that could be thrown
* from the underlying data source. Thus all failures are thrown as instances
* of {@link IonException}, wrapping the original cause. If an application
* wants to handle (say) {@link IOException}s specially, then it needs to
* extract that from the wrappers; the documentation of {@link IonException}
* explains how to do that.
*
* Reader Facets
* Readers are {@link Faceted} and implementations may provide additional
* functionality accessible via the {@link #asFacet(Class)} method.
*
* The {@link SpanProvider} Facet
* This facet is available on all readers that directly consume an Ion source.
* It provides access to the "{@linkplain SpanProvider#currentSpan() current
* span}" covering the reader's current value.
* There is not a current span at the start of the source, immediately
* after a call to {@link #stepIn()} or {@link #stepOut()}, or when the prior
* call to {@link #next()} returned null (meaning: end of container or end of
* stream). In such states, {@link SpanProvider#currentSpan()} will fail.
*
* The {@link SeekableReader} Facet
* This facet is available on all readers except those created from
* an {@link java.io.InputStream InputStream}.
* (See issue amznlabs/ion-java#17.)
* It allows the user to reposition the reader to a {@link Span} over the
* same reader instance or another reader with the same source.
*
* Span Facets
* Readers that support the {@link SpanProvider} facet vend {@link Span}s that
* are also faceted.
*
* The {@link OffsetSpan} Facet
* This facet is support by all readers of Ion binary and text data.
*
* The {@link TextSpan} Facet
* This facet is supported by all readers of Ion text data.
*/
public interface IonReader
extends Closeable, Faceted
{
/**
* Positions this reader on the next sibling after the current value,
* returning the type of that value. Once so positioned the contents of
* this value can be accessed with the {@code *Value()} methods.
*
* A sequence of {@code next()} calls traverses the data at a constant
* depth, within the same container.
* Use {@link #stepIn()} to traverse down into any containers, and
* {@link #stepOut()} to traverse up to the parent container.
*
* @return the type of the next Ion value (never {@link IonType#DATAGRAM}),
* or {@code null} when there are no more elements at the current depth in
* the same container.
*/
public IonType next();
/**
* Positions the reader just before the contents of the current value,
* which must be a container (list, sexp, or struct).
* There's no current value immediately after stepping in, so the next
* thing you'll want to do is call {@link #next()} to move onto the first
* child value (or learn that there's not one).
*
* Stepping into a null container ({@code null.list}, {@code null.sexp},
* or {@code null.struct}) behaves as if the container were empty
* ({@code []}, {@code ()}, or {}).
*
* At any time {@link #stepOut()} may be called to move the cursor back to
* (just after) the parent value, even if there's more children remaining.
*
* @throws IllegalStateException if the current value isn't an Ion container.
*/
public void stepIn();
/**
* Positions the iterator after the current parent's value, moving up one
* level in the data hierarchy.
* There's no current value immediately after stepping out, so the next
* thing you'll want to do is call {@link #next()} to move onto the
* following value.
*
* @throws IllegalStateException if the current value wasn't stepped into.
*/
public void stepOut();
/**
* Returns the depth into the Ion value that this reader has traversed.
* At top level the depth is 0, and it increases by one on each call to
* {@link #stepIn()}.
*/
public int getDepth();
/**
* Returns the symbol table that is applicable to the current value.
* This may be either a system or local symbol table.
*/
public SymbolTable getSymbolTable();
/**
* Returns the type of the current value, or null if there is no
* current value.
*/
public IonType getType();
/**
* Returns an {@link IntegerSize} representing the smallest-possible
* Java type of the Ion {@code int} at the current value.
*
* If the current value is {@code null.int} or is not an Ion
* {@code int}, or if there is no current value, {@code null} will
* be returned.
*
* @see IonInt#getIntegerSize()
*/
public IntegerSize getIntegerSize();
/**
* Return the annotations of the current value as an array of strings.
*
* @return the (ordered) annotations on the current value, or an empty
* array (not {@code null}) if there are none.
*
* @throws UnknownSymbolException if any annotation has unknown text.
*/
public String[] getTypeAnnotations();
/**
* Gets the current value's annotations as symbol tokens (text + ID).
*
* @return the (ordered) annotations on the current value, or an empty
* array (not {@code null}) if there are none.
*
*/
public SymbolToken[] getTypeAnnotationSymbols();
/**
* Return the annotations on the curent value as an iterator. The
* iterator is empty (hasNext() returns false on the first call) if
* there are no annotations on the current value.
*
* @throws UnknownSymbolException if any annotation has unknown text.
*
* @return not null.
*/
public Iterator iterateTypeAnnotations();
/**
* Return the field name of the current value. Or null if there is no valid
* current value or if the current value is not a field of a struct.
*
* @throws UnknownSymbolException if the field name has unknown text.
*/
public String getFieldName();
/**
* Gets the current value's field name as a symbol token (text + ID).
* If the text of the token isn't known, the result's
* {@link SymbolToken#getText()} will be null.
* If the symbol ID of the token isn't known, the result's
* {@link SymbolToken#getSid()} will be
* {@link SymbolTable#UNKNOWN_SYMBOL_ID}.
* At least one of the two fields will be defined.
*
* @return null if there is no current value or if the current value is
* not a field of a struct.
*
*/
public SymbolToken getFieldNameSymbol();
/**
* Determines whether the current value is a null Ion value of any type
* (for example, null or null.int).
* It should be called before
* calling getters that return value types (int, long, boolean,
* double).
*/
public boolean isNullValue();
/**
* Determines whether this reader is currently traversing the fields of an
* Ion struct. It returns false if the iteration
* is in a list, a sexp, or a datagram.
*/
public boolean isInStruct();
//=========================================================================
// Value reading
/**
* Returns the current value as an boolean.
* This is only valid when {@link #getType()} returns {@link IonType#BOOL}.
*/
public boolean booleanValue();
/**
* Returns the current value as an int. This is only valid if there is
* an underlying value and the value is of a numeric type (int, float, or
* decimal).
*/
public int intValue();
/**
* Returns the current value as a long. This is only valid if there is
* an underlying value and the value is of a numeric type (int, float, or
* decimal).
*/
public long longValue();
/**
* Returns the current value as a {@link BigInteger}. This is only valid if there
* is an underlying value and the value is of a numeric type (int, float, or
* decimal).
*/
public BigInteger bigIntegerValue();
/**
* Returns the current value as a double. This is only valid if there is
* an underlying value and the value is either float, or decimal.
*/
public double doubleValue();
/**
* Returns the current value as a {@link BigDecimal}.
* This method should not return a {@link Decimal}, so it lacks support for
* negative zeros.
*
* This method is only valid when {@link #getType()} returns
* {@link IonType#DECIMAL}.
*
* @return the current value as a {@link BigDecimal},
* or {@code null} if the current value is {@code null.decimal}.
*/
public BigDecimal bigDecimalValue();
/**
* Returns the current value as a {@link Decimal}, which extends
* {@link BigDecimal} with support for negative zeros.
* This is only valid when {@link #getType()} returns
* {@link IonType#DECIMAL}.
*
* @return the current value as a {@link Decimal},
* or {@code null} if the current value is {@code null.decimal}.
*/
public Decimal decimalValue();
/**
* Returns the current value as a {@link java.util.Date}.
* This is only valid when {@link #getType()} returns
* {@link IonType#TIMESTAMP}.
*
* @return the current value as a {@link Date},
* or {@code null} if the current value is {@code null.timestamp}.
*/
public Date dateValue();
/**
* Returns the current value as a {@link Timestamp}.
* This is only valid when {@link #getType()} returns
* {@link IonType#TIMESTAMP}.
*
* @return the current value as a {@link Timestamp},
* or {@code null} if the current value is {@code null.timestamp}.
*/
public Timestamp timestampValue();
/**
* Returns the current value as a Java String.
* This is only valid when {@link #getType()} returns
* {@link IonType#STRING} or {@link IonType#SYMBOL}.
*
* @throws UnknownSymbolException if the current value is a symbol
* with unknown text.
*
* @see #symbolValue()
*/
public String stringValue();
/**
* Returns the current value as a symbol token (text + ID).
* This is only valid when {@link #getType()} returns
* {@link IonType#SYMBOL}.
*
* @return null if {@link #isNullValue()}
*
*/
public SymbolToken symbolValue();
/**
* Gets the size in bytes of the current lob value.
* This is only valid when {@link #getType()} returns {@link IonType#BLOB}
* or {@link IonType#CLOB}.
*
* @return the lob's size in bytes.
*/
public int byteSize();
/**
* Returns the current value as a newly-allocated byte array.
* This is only valid when {@link #getType()} returns {@link IonType#BLOB}
* or {@link IonType#CLOB}.
*/
public byte[] newBytes();
/**
* Copies the current value into the passed in a byte array.
* This is only valid when {@link #getType()} returns {@link IonType#BLOB}
* or {@link IonType#CLOB}.
*
* @param buffer destination to copy the value into, this must not be null.
* @param offset the first position to copy into, this must be non null and
* less than the length of buffer.
* @param len the number of bytes available in the buffer to copy into,
* this must be long enough to hold the whole value and not extend outside
* of buffer.
*/
public int getBytes(byte[] buffer, int offset, int len);
/**
* Returns the current value as a String using the Ion toString() serialization
* format. This is only valid if there is an underlying value. This is
* logically equivalent to getIonValue().toString() but may be more efficient
* and does not require an IonSystem context to operate.
*/
// 2008-10-30 Disabled this because semantics are cloudy.
// In particular, does this move the cursor beyond the current value?
// Also, this could be problematic to use since other value-extraction
// methods are read-once, so one can't look at the value before calling this.
// public String valueToString();
}