org.apache.commons.math3.geometry.partitioning.utilities.OrderedTuple Maven / Gradle / Ivy
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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,
* 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 org.apache.commons.math3.geometry.partitioning.utilities;
import java.util.Arrays;
import org.apache.commons.math3.util.FastMath;
/** This class implements an ordering operation for T-uples.
*
* Ordering is done by encoding all components of the T-uple into a
* single scalar value and using this value as the sorting
* key. Encoding is performed using the method invented by Georg
* Cantor in 1877 when he proved it was possible to establish a
* bijection between a line and a plane. The binary representations of
* the components of the T-uple are mixed together to form a single
* scalar. This means that the 2k bit of component 0 is
* followed by the 2k bit of component 1, then by the
* 2k bit of component 2 up to the 2k bit of
* component {@code t}, which is followed by the 2k-1
* bit of component 0, followed by the 2k-1 bit of
* component 1 ... The binary representations are extended as needed
* to handle numbers with different scales and a suitable
* 2p offset is added to the components in order to avoid
* negative numbers (this offset is adjusted as needed during the
* comparison operations).
*
* The more interesting property of the encoding method for our
* purpose is that it allows to select all the points that are in a
* given range. This is depicted in dimension 2 by the following
* picture:
*
*
*
* This picture shows a set of 100000 random 2-D pairs having their
* first component between -50 and +150 and their second component
* between -350 and +50. We wanted to extract all pairs having their
* first component between +30 and +70 and their second component
* between -120 and -30. We built the lower left point at coordinates
* (30, -120) and the upper right point at coordinates (70, -30). All
* points smaller than the lower left point are drawn in red and all
* points larger than the upper right point are drawn in blue. The
* green points are between the two limits. This picture shows that
* all the desired points are selected, along with spurious points. In
* this case, we get 15790 points, 4420 of which really belonging to
* the desired rectangle. It is possible to extract very small
* subsets. As an example extracting from the same 100000 points set
* the points having their first component between +30 and +31 and
* their second component between -91 and -90, we get a subset of 11
* points, 2 of which really belonging to the desired rectangle.
*
* the previous selection technique can be applied in all
* dimensions, still using two points to define the interval. The
* first point will have all its components set to their lower bounds
* while the second point will have all its components set to their
* upper bounds.
*
* T-uples with negative infinite or positive infinite components
* are sorted logically.
*
* Since the specification of the {@code Comparator} interface
* allows only {@code ClassCastException} errors, some arbitrary
* choices have been made to handle specific cases. The rationale for
* these choices is to keep regular and consistent T-uples
* together.
*
* - instances with different dimensions are sorted according to
* their dimension regardless of their components values
* - instances with {@code Double.NaN} components are sorted
* after all other ones (even after instances with positive infinite
* components
* - instances with both positive and negative infinite components
* are considered as if they had {@code Double.NaN}
* components
*
*
* @since 3.0
* @deprecated as of 3.4, this class is not used anymore and considered
* to be out of scope of Apache Commons Math
*/
@Deprecated
public class OrderedTuple implements Comparable {
/** Sign bit mask. */
private static final long SIGN_MASK = 0x8000000000000000L;
/** Exponent bits mask. */
private static final long EXPONENT_MASK = 0x7ff0000000000000L;
/** Mantissa bits mask. */
private static final long MANTISSA_MASK = 0x000fffffffffffffL;
/** Implicit MSB for normalized numbers. */
private static final long IMPLICIT_ONE = 0x0010000000000000L;
/** Double components of the T-uple. */
private double[] components;
/** Offset scale. */
private int offset;
/** Least Significant Bit scale. */
private int lsb;
/** Ordering encoding of the double components. */
private long[] encoding;
/** Positive infinity marker. */
private boolean posInf;
/** Negative infinity marker. */
private boolean negInf;
/** Not A Number marker. */
private boolean nan;
/** Build an ordered T-uple from its components.
* @param components double components of the T-uple
*/
public OrderedTuple(final double ... components) {
this.components = components.clone();
int msb = Integer.MIN_VALUE;
lsb = Integer.MAX_VALUE;
posInf = false;
negInf = false;
nan = false;
for (int i = 0; i < components.length; ++i) {
if (Double.isInfinite(components[i])) {
if (components[i] < 0) {
negInf = true;
} else {
posInf = true;
}
} else if (Double.isNaN(components[i])) {
nan = true;
} else {
final long b = Double.doubleToLongBits(components[i]);
final long m = mantissa(b);
if (m != 0) {
final int e = exponent(b);
msb = FastMath.max(msb, e + computeMSB(m));
lsb = FastMath.min(lsb, e + computeLSB(m));
}
}
}
if (posInf && negInf) {
// instance cannot be sorted logically
posInf = false;
negInf = false;
nan = true;
}
if (lsb <= msb) {
// encode the T-upple with the specified offset
encode(msb + 16);
} else {
encoding = new long[] {
0x0L
};
}
}
/** Encode the T-uple with a given offset.
* @param minOffset minimal scale of the offset to add to all
* components (must be greater than the MSBs of all components)
*/
private void encode(final int minOffset) {
// choose an offset with some margins
offset = minOffset + 31;
offset -= offset % 32;
if ((encoding != null) && (encoding.length == 1) && (encoding[0] == 0x0L)) {
// the components are all zeroes
return;
}
// allocate an integer array to encode the components (we use only
// 63 bits per element because there is no unsigned long in Java)
final int neededBits = offset + 1 - lsb;
final int neededLongs = (neededBits + 62) / 63;
encoding = new long[components.length * neededLongs];
// mix the bits from all components
int eIndex = 0;
int shift = 62;
long word = 0x0L;
for (int k = offset; eIndex < encoding.length; --k) {
for (int vIndex = 0; vIndex < components.length; ++vIndex) {
if (getBit(vIndex, k) != 0) {
word |= 0x1L << shift;
}
if (shift-- == 0) {
encoding[eIndex++] = word;
word = 0x0L;
shift = 62;
}
}
}
}
/** Compares this ordered T-uple with the specified object.
* The ordering method is detailed in the general description of
* the class. Its main property is to be consistent with distance:
* geometrically close T-uples stay close to each other when stored
* in a sorted collection using this comparison method.
* T-uples with negative infinite, positive infinite are sorted
* logically.
* Some arbitrary choices have been made to handle specific
* cases. The rationale for these choices is to keep
* normal and consistent T-uples together.
*
* - instances with different dimensions are sorted according to
* their dimension regardless of their components values
* - instances with {@code Double.NaN} components are sorted
* after all other ones (evan after instances with positive infinite
* components
* - instances with both positive and negative infinite components
* are considered as if they had {@code Double.NaN}
* components
*
* @param ot T-uple to compare instance with
* @return a negative integer if the instance is less than the
* object, zero if they are equal, or a positive integer if the
* instance is greater than the object
*/
public int compareTo(final OrderedTuple ot) {
if (components.length == ot.components.length) {
if (nan) {
return +1;
} else if (ot.nan) {
return -1;
} else if (negInf || ot.posInf) {
return -1;
} else if (posInf || ot.negInf) {
return +1;
} else {
if (offset < ot.offset) {
encode(ot.offset);
} else if (offset > ot.offset) {
ot.encode(offset);
}
final int limit = FastMath.min(encoding.length, ot.encoding.length);
for (int i = 0; i < limit; ++i) {
if (encoding[i] < ot.encoding[i]) {
return -1;
} else if (encoding[i] > ot.encoding[i]) {
return +1;
}
}
if (encoding.length < ot.encoding.length) {
return -1;
} else if (encoding.length > ot.encoding.length) {
return +1;
} else {
return 0;
}
}
}
return components.length - ot.components.length;
}
/** {@inheritDoc} */
@Override
public boolean equals(final Object other) {
if (this == other) {
return true;
} else if (other instanceof OrderedTuple) {
return compareTo((OrderedTuple) other) == 0;
} else {
return false;
}
}
/** {@inheritDoc} */
@Override
public int hashCode() {
// the following constants are arbitrary small primes
final int multiplier = 37;
final int trueHash = 97;
final int falseHash = 71;
// hash fields and combine them
// (we rely on the multiplier to have different combined weights
// for all int fields and all boolean fields)
int hash = Arrays.hashCode(components);
hash = hash * multiplier + offset;
hash = hash * multiplier + lsb;
hash = hash * multiplier + (posInf ? trueHash : falseHash);
hash = hash * multiplier + (negInf ? trueHash : falseHash);
hash = hash * multiplier + (nan ? trueHash : falseHash);
return hash;
}
/** Get the components array.
* @return array containing the T-uple components
*/
public double[] getComponents() {
return components.clone();
}
/** Extract the sign from the bits of a double.
* @param bits binary representation of the double
* @return sign bit (zero if positive, non zero if negative)
*/
private static long sign(final long bits) {
return bits & SIGN_MASK;
}
/** Extract the exponent from the bits of a double.
* @param bits binary representation of the double
* @return exponent
*/
private static int exponent(final long bits) {
return ((int) ((bits & EXPONENT_MASK) >> 52)) - 1075;
}
/** Extract the mantissa from the bits of a double.
* @param bits binary representation of the double
* @return mantissa
*/
private static long mantissa(final long bits) {
return ((bits & EXPONENT_MASK) == 0) ?
((bits & MANTISSA_MASK) << 1) : // subnormal number
(IMPLICIT_ONE | (bits & MANTISSA_MASK)); // normal number
}
/** Compute the most significant bit of a long.
* @param l long from which the most significant bit is requested
* @return scale of the most significant bit of {@code l},
* or 0 if {@code l} is zero
* @see #computeLSB
*/
private static int computeMSB(final long l) {
long ll = l;
long mask = 0xffffffffL;
int scale = 32;
int msb = 0;
while (scale != 0) {
if ((ll & mask) != ll) {
msb |= scale;
ll >>= scale;
}
scale >>= 1;
mask >>= scale;
}
return msb;
}
/** Compute the least significant bit of a long.
* @param l long from which the least significant bit is requested
* @return scale of the least significant bit of {@code l},
* or 63 if {@code l} is zero
* @see #computeMSB
*/
private static int computeLSB(final long l) {
long ll = l;
long mask = 0xffffffff00000000L;
int scale = 32;
int lsb = 0;
while (scale != 0) {
if ((ll & mask) == ll) {
lsb |= scale;
ll >>= scale;
}
scale >>= 1;
mask >>= scale;
}
return lsb;
}
/** Get a bit from the mantissa of a double.
* @param i index of the component
* @param k scale of the requested bit
* @return the specified bit (either 0 or 1), after the offset has
* been added to the double
*/
private int getBit(final int i, final int k) {
final long bits = Double.doubleToLongBits(components[i]);
final int e = exponent(bits);
if ((k < e) || (k > offset)) {
return 0;
} else if (k == offset) {
return (sign(bits) == 0L) ? 1 : 0;
} else if (k > (e + 52)) {
return (sign(bits) == 0L) ? 0 : 1;
} else {
final long m = (sign(bits) == 0L) ? mantissa(bits) : -mantissa(bits);
return (int) ((m >> (k - e)) & 0x1L);
}
}
}