Class NumericRangeQuery<T extends java.lang.Number>
- java.lang.Object
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- org.apache.lucene.search.Query
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- org.apache.lucene.search.MultiTermQuery
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- org.apache.lucene.search.NumericRangeQuery<T>
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- All Implemented Interfaces:
java.lang.Cloneable
public final class NumericRangeQuery<T extends java.lang.Number> extends MultiTermQuery
A
Query
that matches numeric values within a specified range. To use this, you must first index the numeric values usingIntField
,FloatField
,LongField
orDoubleField
(expert:NumericTokenStream
). If your terms are instead textual, you should useTermRangeQuery
.NumericRangeFilter
is the filter equivalent of this query.You create a new NumericRangeQuery with the static factory methods, eg:
Query q = NumericRangeQuery.newFloatRange("weight", 0.03f, 0.10f, true, true);
matches all documents whose float valued "weight" field ranges from 0.03 to 0.10, inclusive.The performance of NumericRangeQuery is much better than the corresponding
TermRangeQuery
because the number of terms that must be searched is usually far fewer, thanks to trie indexing, described below.You can optionally specify a
precisionStep
when creating this query. This is necessary if you've changed this configuration from its default (4) during indexing. Lower values consume more disk space but speed up searching. Suitable values are between 1 and 8. A good starting point to test is 4, which is the default value for allNumeric*
classes. See below for details.This query defaults to MultiTermQuery.CONSTANT_SCORE_AUTO_REWRITE_DEFAULT. With precision steps of ≤4, this query can be run with one of the BooleanQuery rewrite methods without changing BooleanQuery's default max clause count.
How it works
See the publication about panFMP, where this algorithm was described (referred to as
TrieRangeQuery
):Schindler, U, Diepenbroek, M, 2008. Generic XML-based Framework for Metadata Portals. Computers & Geosciences 34 (12), 1947-1955. doi:10.1016/j.cageo.2008.02.023
A quote from this paper: Because Apache Lucene is a full-text search engine and not a conventional database, it cannot handle numerical ranges (e.g., field value is inside user defined bounds, even dates are numerical values). We have developed an extension to Apache Lucene that stores the numerical values in a special string-encoded format with variable precision (all numerical values like doubles, longs, floats, and ints are converted to lexicographic sortable string representations and stored with different precisions (for a more detailed description of how the values are stored, see
NumericUtils
). A range is then divided recursively into multiple intervals for searching: The center of the range is searched only with the lowest possible precision in the trie, while the boundaries are matched more exactly. This reduces the number of terms dramatically.For the variant that stores long values in 8 different precisions (each reduced by 8 bits) that uses a lowest precision of 1 byte, the index contains only a maximum of 256 distinct values in the lowest precision. Overall, a range could consist of a theoretical maximum of
7*255*2 + 255 = 3825
distinct terms (when there is a term for every distinct value of an 8-byte-number in the index and the range covers almost all of them; a maximum of 255 distinct values is used because it would always be possible to reduce the full 256 values to one term with degraded precision). In practice, we have seen up to 300 terms in most cases (index with 500,000 metadata records and a uniform value distribution).Precision Step
You can choose any
precisionStep
when encoding values. Lower step values mean more precisions and so more terms in index (and index gets larger). The number of indexed terms per value is (those are generated byNumericTokenStream
):indexedTermsPerValue = ceil(bitsPerValue / precisionStep)
As the lower precision terms are shared by many values, the additional terms only slightly grow the term dictionary (approx. 7% forprecisionStep=4
), but have a larger impact on the postings (the postings file will have more entries, as every document is linked toindexedTermsPerValue
terms instead of one). The formula to estimate the growth of the term dictionary in comparison to one term per value:On the other hand, if the
precisionStep
is smaller, the maximum number of terms to match reduces, which optimizes query speed. The formula to calculate the maximum number of terms that will be visited while executing the query is:For longs stored using a precision step of 4,
maxQueryTerms = 15*15*2 + 15 = 465
, and for a precision step of 2,maxQueryTerms = 31*3*2 + 3 = 189
. But the faster search speed is reduced by more seeking in the term enum of the index. Because of this, the idealprecisionStep
value can only be found out by testing. Important: You can index with a lower precision step value and test search speed using a multiple of the original step value.Good values for
precisionStep
are depending on usage and data type:- The default for all data types is 4, which is used, when no
precisionStep
is given. - Ideal value in most cases for 64 bit data types (long, double) is 6 or 8.
- Ideal value in most cases for 32 bit data types (int, float) is 4.
- For low cardinality fields larger precision steps are good. If the cardinality is < 100, it is
fair to use
Integer.MAX_VALUE
(see below). - Steps ≥64 for long/double and ≥32 for int/float produces one token
per value in the index and querying is as slow as a conventional
TermRangeQuery
. But it can be used to produce fields, that are solely used for sorting (in this case simply useInteger.MAX_VALUE
asprecisionStep
). UsingIntField
,LongField
,FloatField
orDoubleField
for sorting is ideal, because building the field cache is much faster than with text-only numbers. These fields have one term per value and therefore also work with term enumeration for building distinct lists (e.g. facets / preselected values to search for). Sorting is also possible with range query optimized fields using one of the aboveprecisionSteps
.
Comparisons of the different types of RangeQueries on an index with about 500,000 docs showed that
TermRangeQuery
in boolean rewrite mode (with raisedBooleanQuery
clause count) took about 30-40 secs to complete,TermRangeQuery
in constant score filter rewrite mode took 5 secs and executing this class took <100ms to complete (on an Opteron64 machine, Java 1.5, 8 bit precision step). This query type was developed for a geographic portal, where the performance for e.g. bounding boxes or exact date/time stamps is important.- Since:
- 2.9
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Nested Class Summary
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Nested classes/interfaces inherited from class org.apache.lucene.search.MultiTermQuery
MultiTermQuery.ConstantScoreAutoRewrite, MultiTermQuery.RewriteMethod, MultiTermQuery.TopTermsBoostOnlyBooleanQueryRewrite, MultiTermQuery.TopTermsScoringBooleanQueryRewrite
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Field Summary
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Fields inherited from class org.apache.lucene.search.MultiTermQuery
CONSTANT_SCORE_AUTO_REWRITE_DEFAULT, CONSTANT_SCORE_BOOLEAN_QUERY_REWRITE, CONSTANT_SCORE_FILTER_REWRITE, SCORING_BOOLEAN_QUERY_REWRITE
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Method Summary
All Methods Static Methods Instance Methods Concrete Methods Modifier and Type Method Description boolean
equals(java.lang.Object o)
T
getMax()
Returns the upper value of this range queryT
getMin()
Returns the lower value of this range queryint
getPrecisionStep()
Returns the precision step.int
hashCode()
boolean
includesMax()
Returnstrue
if the upper endpoint is inclusiveboolean
includesMin()
Returnstrue
if the lower endpoint is inclusivestatic NumericRangeQuery<java.lang.Double>
newDoubleRange(java.lang.String field, int precisionStep, java.lang.Double min, java.lang.Double max, boolean minInclusive, boolean maxInclusive)
Factory that creates aNumericRangeQuery
, that queries adouble
range using the givenprecisionStep
.static NumericRangeQuery<java.lang.Double>
newDoubleRange(java.lang.String field, java.lang.Double min, java.lang.Double max, boolean minInclusive, boolean maxInclusive)
Factory that creates aNumericRangeQuery
, that queries adouble
range using the defaultprecisionStep
NumericUtils.PRECISION_STEP_DEFAULT
(4).static NumericRangeQuery<java.lang.Float>
newFloatRange(java.lang.String field, int precisionStep, java.lang.Float min, java.lang.Float max, boolean minInclusive, boolean maxInclusive)
static NumericRangeQuery<java.lang.Float>
newFloatRange(java.lang.String field, java.lang.Float min, java.lang.Float max, boolean minInclusive, boolean maxInclusive)
Factory that creates aNumericRangeQuery
, that queries afloat
range using the defaultprecisionStep
NumericUtils.PRECISION_STEP_DEFAULT
(4).static NumericRangeQuery<java.lang.Integer>
newIntRange(java.lang.String field, int precisionStep, java.lang.Integer min, java.lang.Integer max, boolean minInclusive, boolean maxInclusive)
static NumericRangeQuery<java.lang.Integer>
newIntRange(java.lang.String field, java.lang.Integer min, java.lang.Integer max, boolean minInclusive, boolean maxInclusive)
Factory that creates aNumericRangeQuery
, that queries aint
range using the defaultprecisionStep
NumericUtils.PRECISION_STEP_DEFAULT
(4).static NumericRangeQuery<java.lang.Long>
newLongRange(java.lang.String field, int precisionStep, java.lang.Long min, java.lang.Long max, boolean minInclusive, boolean maxInclusive)
static NumericRangeQuery<java.lang.Long>
newLongRange(java.lang.String field, java.lang.Long min, java.lang.Long max, boolean minInclusive, boolean maxInclusive)
Factory that creates aNumericRangeQuery
, that queries along
range using the defaultprecisionStep
NumericUtils.PRECISION_STEP_DEFAULT
(4).java.lang.String
toString(java.lang.String field)
Prints a query to a string, withfield
assumed to be the default field and omitted.-
Methods inherited from class org.apache.lucene.search.MultiTermQuery
getField, getRewriteMethod, rewrite, setRewriteMethod
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Methods inherited from class org.apache.lucene.search.Query
clone, createWeight, extractTerms, getBoost, setBoost, toString
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Method Detail
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newLongRange
public static NumericRangeQuery<java.lang.Long> newLongRange(java.lang.String field, int precisionStep, java.lang.Long min, java.lang.Long max, boolean minInclusive, boolean maxInclusive)
Factory that creates aNumericRangeQuery
, that queries along
range using the givenprecisionStep
. You can have half-open ranges (which are in fact </≤ or >/≥ queries) by setting the min or max value tonull
. By setting inclusive to false, it will match all documents excluding the bounds, with inclusive on, the boundaries are hits, too.
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newLongRange
public static NumericRangeQuery<java.lang.Long> newLongRange(java.lang.String field, java.lang.Long min, java.lang.Long max, boolean minInclusive, boolean maxInclusive)
Factory that creates aNumericRangeQuery
, that queries along
range using the defaultprecisionStep
NumericUtils.PRECISION_STEP_DEFAULT
(4). You can have half-open ranges (which are in fact </≤ or >/≥ queries) by setting the min or max value tonull
. By setting inclusive to false, it will match all documents excluding the bounds, with inclusive on, the boundaries are hits, too.
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newIntRange
public static NumericRangeQuery<java.lang.Integer> newIntRange(java.lang.String field, int precisionStep, java.lang.Integer min, java.lang.Integer max, boolean minInclusive, boolean maxInclusive)
Factory that creates aNumericRangeQuery
, that queries aint
range using the givenprecisionStep
. You can have half-open ranges (which are in fact </≤ or >/≥ queries) by setting the min or max value tonull
. By setting inclusive to false, it will match all documents excluding the bounds, with inclusive on, the boundaries are hits, too.
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newIntRange
public static NumericRangeQuery<java.lang.Integer> newIntRange(java.lang.String field, java.lang.Integer min, java.lang.Integer max, boolean minInclusive, boolean maxInclusive)
Factory that creates aNumericRangeQuery
, that queries aint
range using the defaultprecisionStep
NumericUtils.PRECISION_STEP_DEFAULT
(4). You can have half-open ranges (which are in fact </≤ or >/≥ queries) by setting the min or max value tonull
. By setting inclusive to false, it will match all documents excluding the bounds, with inclusive on, the boundaries are hits, too.
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newDoubleRange
public static NumericRangeQuery<java.lang.Double> newDoubleRange(java.lang.String field, int precisionStep, java.lang.Double min, java.lang.Double max, boolean minInclusive, boolean maxInclusive)
Factory that creates aNumericRangeQuery
, that queries adouble
range using the givenprecisionStep
. You can have half-open ranges (which are in fact </≤ or >/≥ queries) by setting the min or max value tonull
.Double.NaN
will never match a half-open range, to hitNaN
use a query withmin == max == Double.NaN
. By setting inclusive to false, it will match all documents excluding the bounds, with inclusive on, the boundaries are hits, too.
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newDoubleRange
public static NumericRangeQuery<java.lang.Double> newDoubleRange(java.lang.String field, java.lang.Double min, java.lang.Double max, boolean minInclusive, boolean maxInclusive)
Factory that creates aNumericRangeQuery
, that queries adouble
range using the defaultprecisionStep
NumericUtils.PRECISION_STEP_DEFAULT
(4). You can have half-open ranges (which are in fact </≤ or >/≥ queries) by setting the min or max value tonull
.Double.NaN
will never match a half-open range, to hitNaN
use a query withmin == max == Double.NaN
. By setting inclusive to false, it will match all documents excluding the bounds, with inclusive on, the boundaries are hits, too.
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newFloatRange
public static NumericRangeQuery<java.lang.Float> newFloatRange(java.lang.String field, int precisionStep, java.lang.Float min, java.lang.Float max, boolean minInclusive, boolean maxInclusive)
Factory that creates aNumericRangeQuery
, that queries afloat
range using the givenprecisionStep
. You can have half-open ranges (which are in fact </≤ or >/≥ queries) by setting the min or max value tonull
.Float.NaN
will never match a half-open range, to hitNaN
use a query withmin == max == Float.NaN
. By setting inclusive to false, it will match all documents excluding the bounds, with inclusive on, the boundaries are hits, too.
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newFloatRange
public static NumericRangeQuery<java.lang.Float> newFloatRange(java.lang.String field, java.lang.Float min, java.lang.Float max, boolean minInclusive, boolean maxInclusive)
Factory that creates aNumericRangeQuery
, that queries afloat
range using the defaultprecisionStep
NumericUtils.PRECISION_STEP_DEFAULT
(4). You can have half-open ranges (which are in fact </≤ or >/≥ queries) by setting the min or max value tonull
.Float.NaN
will never match a half-open range, to hitNaN
use a query withmin == max == Float.NaN
. By setting inclusive to false, it will match all documents excluding the bounds, with inclusive on, the boundaries are hits, too.
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includesMin
public boolean includesMin()
Returnstrue
if the lower endpoint is inclusive
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includesMax
public boolean includesMax()
Returnstrue
if the upper endpoint is inclusive
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getMin
public T getMin()
Returns the lower value of this range query
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getMax
public T getMax()
Returns the upper value of this range query
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getPrecisionStep
public int getPrecisionStep()
Returns the precision step.
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toString
public java.lang.String toString(java.lang.String field)
Description copied from class:Query
Prints a query to a string, withfield
assumed to be the default field and omitted.
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equals
public final boolean equals(java.lang.Object o)
- Overrides:
equals
in classMultiTermQuery
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hashCode
public final int hashCode()
- Overrides:
hashCode
in classMultiTermQuery
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