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/*
 * Copyright (C) 2014 The Guava Authors
 *
 * 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 com.google.common.math;

import static com.google.common.base.Preconditions.checkArgument;
import static java.lang.Double.NEGATIVE_INFINITY;
import static java.lang.Double.NaN;
import static java.lang.Double.POSITIVE_INFINITY;
import static java.util.Arrays.sort;
import static java.util.Collections.unmodifiableMap;

import com.google.common.annotations.Beta;
import com.google.common.annotations.GwtIncompatible;
import com.google.common.primitives.Doubles;
import com.google.common.primitives.Ints;
import java.math.RoundingMode;
import java.util.Collection;
import java.util.LinkedHashMap;
import java.util.Map;

/**
 * Provides a fluent API for calculating quantiles.
 *
 * 

Examples

* *

To compute the median: * *

{@code
 * double myMedian = median().compute(myDataset);
 * }
* * where {@link #median()} has been statically imported. * *

To compute the 99th percentile: * *

{@code
 * double myPercentile99 = percentiles().index(99).compute(myDataset);
 * }
* * where {@link #percentiles()} has been statically imported. * *

To compute median and the 90th and 99th percentiles: * *

{@code
 * Map myPercentiles =
 *     percentiles().indexes(50, 90, 99).compute(myDataset);
 * }
* * where {@link #percentiles()} has been statically imported: {@code myPercentiles} maps the keys * 50, 90, and 99, to their corresponding quantile values. * *

To compute quartiles, use {@link #quartiles()} instead of {@link #percentiles()}. To compute * arbitrary q-quantiles, use {@link #scale scale(q)}. * *

These examples all take a copy of your dataset. If you have a double array, you are okay with * it being arbitrarily reordered, and you want to avoid that copy, you can use {@code * computeInPlace} instead of {@code compute}. * *

Definition and notes on interpolation

* *

The definition of the kth q-quantile of N values is as follows: define x = k * (N - 1) / q; if * x is an integer, the result is the value which would appear at index x in the sorted dataset * (unless there are {@link Double#NaN NaN} values, see below); otherwise, the result is the average * of the values which would appear at the indexes floor(x) and ceil(x) weighted by (1-frac(x)) and * frac(x) respectively. This is the same definition as used by Excel and by S, it is the Type 7 * definition in R, and it is * described by * wikipedia as providing "Linear interpolation of the modes for the order statistics for the * uniform distribution on [0,1]." * *

Handling of non-finite values

* *

If any values in the input are {@link Double#NaN NaN} then all values returned are {@link * Double#NaN NaN}. (This is the one occasion when the behaviour is not the same as you'd get from * sorting with {@link java.util.Arrays#sort(double[]) Arrays.sort(double[])} or {@link * java.util.Collections#sort(java.util.List) Collections.sort(List<Double>)} and selecting * the required value(s). Those methods would sort {@link Double#NaN NaN} as if it is greater than * any other value and place them at the end of the dataset, even after {@link * Double#POSITIVE_INFINITY POSITIVE_INFINITY}.) * *

Otherwise, {@link Double#NEGATIVE_INFINITY NEGATIVE_INFINITY} and {@link * Double#POSITIVE_INFINITY POSITIVE_INFINITY} sort to the beginning and the end of the dataset, as * you would expect. * *

If required to do a weighted average between an infinity and a finite value, or between an * infinite value and itself, the infinite value is returned. If required to do a weighted average * between {@link Double#NEGATIVE_INFINITY NEGATIVE_INFINITY} and {@link Double#POSITIVE_INFINITY * POSITIVE_INFINITY}, {@link Double#NaN NaN} is returned (note that this will only happen if the * dataset contains no finite values). * *

Performance

* *

The average time complexity of the computation is O(N) in the size of the dataset. There is a * worst case time complexity of O(N^2). You are extremely unlikely to hit this quadratic case on * randomly ordered data (the probability decreases faster than exponentially in N), but if you are * passing in unsanitized user data then a malicious user could force it. A light shuffle of the * data using an unpredictable seed should normally be enough to thwart this attack. * *

The time taken to compute multiple quantiles on the same dataset using {@link Scale#indexes * indexes} is generally less than the total time taken to compute each of them separately, and * sometimes much less. For example, on a large enough dataset, computing the 90th and 99th * percentiles together takes about 55% as long as computing them separately. * *

When calling {@link ScaleAndIndex#compute} (in {@linkplain ScaleAndIndexes#compute either * form}), the memory requirement is 8*N bytes for the copy of the dataset plus an overhead which is * independent of N (but depends on the quantiles being computed). When calling {@link * ScaleAndIndex#computeInPlace computeInPlace} (in {@linkplain ScaleAndIndexes#computeInPlace * either form}), only the overhead is required. The number of object allocations is independent of * N in both cases. * * @author Pete Gillin * @since 20.0 */ @Beta @GwtIncompatible @ElementTypesAreNonnullByDefault public final class Quantiles { /** Specifies the computation of a median (i.e. the 1st 2-quantile). */ public static ScaleAndIndex median() { return scale(2).index(1); } /** Specifies the computation of quartiles (i.e. 4-quantiles). */ public static Scale quartiles() { return scale(4); } /** Specifies the computation of percentiles (i.e. 100-quantiles). */ public static Scale percentiles() { return scale(100); } /** * Specifies the computation of q-quantiles. * * @param scale the scale for the quantiles to be calculated, i.e. the q of the q-quantiles, which * must be positive */ public static Scale scale(int scale) { return new Scale(scale); } /** * Describes the point in a fluent API chain where only the scale (i.e. the q in q-quantiles) has * been specified. * * @since 20.0 */ public static final class Scale { private final int scale; private Scale(int scale) { checkArgument(scale > 0, "Quantile scale must be positive"); this.scale = scale; } /** * Specifies a single quantile index to be calculated, i.e. the k in the kth q-quantile. * * @param index the quantile index, which must be in the inclusive range [0, q] for q-quantiles */ public ScaleAndIndex index(int index) { return new ScaleAndIndex(scale, index); } /** * Specifies multiple quantile indexes to be calculated, each index being the k in the kth * q-quantile. * * @param indexes the quantile indexes, each of which must be in the inclusive range [0, q] for * q-quantiles; the order of the indexes is unimportant, duplicates will be ignored, and the * set will be snapshotted when this method is called * @throws IllegalArgumentException if {@code indexes} is empty */ public ScaleAndIndexes indexes(int... indexes) { return new ScaleAndIndexes(scale, indexes.clone()); } /** * Specifies multiple quantile indexes to be calculated, each index being the k in the kth * q-quantile. * * @param indexes the quantile indexes, each of which must be in the inclusive range [0, q] for * q-quantiles; the order of the indexes is unimportant, duplicates will be ignored, and the * set will be snapshotted when this method is called * @throws IllegalArgumentException if {@code indexes} is empty */ public ScaleAndIndexes indexes(Collection indexes) { return new ScaleAndIndexes(scale, Ints.toArray(indexes)); } } /** * Describes the point in a fluent API chain where the scale and a single quantile index (i.e. the * q and the k in the kth q-quantile) have been specified. * * @since 20.0 */ public static final class ScaleAndIndex { private final int scale; private final int index; private ScaleAndIndex(int scale, int index) { checkIndex(index, scale); this.scale = scale; this.index = index; } /** * Computes the quantile value of the given dataset. * * @param dataset the dataset to do the calculation on, which must be non-empty, which will be * cast to doubles (with any associated lost of precision), and which will not be mutated by * this call (it is copied instead) * @return the quantile value */ public double compute(Collection dataset) { return computeInPlace(Doubles.toArray(dataset)); } /** * Computes the quantile value of the given dataset. * * @param dataset the dataset to do the calculation on, which must be non-empty, which will not * be mutated by this call (it is copied instead) * @return the quantile value */ public double compute(double... dataset) { return computeInPlace(dataset.clone()); } /** * Computes the quantile value of the given dataset. * * @param dataset the dataset to do the calculation on, which must be non-empty, which will be * cast to doubles (with any associated lost of precision), and which will not be mutated by * this call (it is copied instead) * @return the quantile value */ public double compute(long... dataset) { return computeInPlace(longsToDoubles(dataset)); } /** * Computes the quantile value of the given dataset. * * @param dataset the dataset to do the calculation on, which must be non-empty, which will be * cast to doubles, and which will not be mutated by this call (it is copied instead) * @return the quantile value */ public double compute(int... dataset) { return computeInPlace(intsToDoubles(dataset)); } /** * Computes the quantile value of the given dataset, performing the computation in-place. * * @param dataset the dataset to do the calculation on, which must be non-empty, and which will * be arbitrarily reordered by this method call * @return the quantile value */ public double computeInPlace(double... dataset) { checkArgument(dataset.length > 0, "Cannot calculate quantiles of an empty dataset"); if (containsNaN(dataset)) { return NaN; } // Calculate the quotient and remainder in the integer division x = k * (N-1) / q, i.e. // index * (dataset.length - 1) / scale. If there is no remainder, we can just find the value // whose index in the sorted dataset equals the quotient; if there is a remainder, we // interpolate between that and the next value. // Since index and (dataset.length - 1) are non-negative ints, their product can be expressed // as a long, without risk of overflow: long numerator = (long) index * (dataset.length - 1); // Since scale is a positive int, index is in [0, scale], and (dataset.length - 1) is a // non-negative int, we can do long-arithmetic on index * (dataset.length - 1) / scale to get // a rounded ratio and a remainder which can be expressed as ints, without risk of overflow: int quotient = (int) LongMath.divide(numerator, scale, RoundingMode.DOWN); int remainder = (int) (numerator - (long) quotient * scale); selectInPlace(quotient, dataset, 0, dataset.length - 1); if (remainder == 0) { return dataset[quotient]; } else { selectInPlace(quotient + 1, dataset, quotient + 1, dataset.length - 1); return interpolate(dataset[quotient], dataset[quotient + 1], remainder, scale); } } } /** * Describes the point in a fluent API chain where the scale and a multiple quantile indexes (i.e. * the q and a set of values for the k in the kth q-quantile) have been specified. * * @since 20.0 */ public static final class ScaleAndIndexes { private final int scale; private final int[] indexes; private ScaleAndIndexes(int scale, int[] indexes) { for (int index : indexes) { checkIndex(index, scale); } checkArgument(indexes.length > 0, "Indexes must be a non empty array"); this.scale = scale; this.indexes = indexes; } /** * Computes the quantile values of the given dataset. * * @param dataset the dataset to do the calculation on, which must be non-empty, which will be * cast to doubles (with any associated lost of precision), and which will not be mutated by * this call (it is copied instead) * @return an unmodifiable, ordered map of results: the keys will be the specified quantile * indexes, and the values the corresponding quantile values. When iterating, entries in the * map are ordered by quantile index in the same order they were passed to the {@code * indexes} method. */ public Map compute(Collection dataset) { return computeInPlace(Doubles.toArray(dataset)); } /** * Computes the quantile values of the given dataset. * * @param dataset the dataset to do the calculation on, which must be non-empty, which will not * be mutated by this call (it is copied instead) * @return an unmodifiable, ordered map of results: the keys will be the specified quantile * indexes, and the values the corresponding quantile values. When iterating, entries in the * map are ordered by quantile index in the same order they were passed to the {@code * indexes} method. */ public Map compute(double... dataset) { return computeInPlace(dataset.clone()); } /** * Computes the quantile values of the given dataset. * * @param dataset the dataset to do the calculation on, which must be non-empty, which will be * cast to doubles (with any associated lost of precision), and which will not be mutated by * this call (it is copied instead) * @return an unmodifiable, ordered map of results: the keys will be the specified quantile * indexes, and the values the corresponding quantile values. When iterating, entries in the * map are ordered by quantile index in the same order they were passed to the {@code * indexes} method. */ public Map compute(long... dataset) { return computeInPlace(longsToDoubles(dataset)); } /** * Computes the quantile values of the given dataset. * * @param dataset the dataset to do the calculation on, which must be non-empty, which will be * cast to doubles, and which will not be mutated by this call (it is copied instead) * @return an unmodifiable, ordered map of results: the keys will be the specified quantile * indexes, and the values the corresponding quantile values. When iterating, entries in the * map are ordered by quantile index in the same order they were passed to the {@code * indexes} method. */ public Map compute(int... dataset) { return computeInPlace(intsToDoubles(dataset)); } /** * Computes the quantile values of the given dataset, performing the computation in-place. * * @param dataset the dataset to do the calculation on, which must be non-empty, and which will * be arbitrarily reordered by this method call * @return an unmodifiable, ordered map of results: the keys will be the specified quantile * indexes, and the values the corresponding quantile values. When iterating, entries in the * map are ordered by quantile index in the same order that the indexes were passed to the * {@code indexes} method. */ public Map computeInPlace(double... dataset) { checkArgument(dataset.length > 0, "Cannot calculate quantiles of an empty dataset"); if (containsNaN(dataset)) { Map nanMap = new LinkedHashMap<>(); for (int index : indexes) { nanMap.put(index, NaN); } return unmodifiableMap(nanMap); } // Calculate the quotients and remainders in the integer division x = k * (N - 1) / q, i.e. // index * (dataset.length - 1) / scale for each index in indexes. For each, if there is no // remainder, we can just select the value whose index in the sorted dataset equals the // quotient; if there is a remainder, we interpolate between that and the next value. int[] quotients = new int[indexes.length]; int[] remainders = new int[indexes.length]; // The indexes to select. In the worst case, we'll need one each side of each quantile. int[] requiredSelections = new int[indexes.length * 2]; int requiredSelectionsCount = 0; for (int i = 0; i < indexes.length; i++) { // Since index and (dataset.length - 1) are non-negative ints, their product can be // expressed as a long, without risk of overflow: long numerator = (long) indexes[i] * (dataset.length - 1); // Since scale is a positive int, index is in [0, scale], and (dataset.length - 1) is a // non-negative int, we can do long-arithmetic on index * (dataset.length - 1) / scale to // get a rounded ratio and a remainder which can be expressed as ints, without risk of // overflow: int quotient = (int) LongMath.divide(numerator, scale, RoundingMode.DOWN); int remainder = (int) (numerator - (long) quotient * scale); quotients[i] = quotient; remainders[i] = remainder; requiredSelections[requiredSelectionsCount] = quotient; requiredSelectionsCount++; if (remainder != 0) { requiredSelections[requiredSelectionsCount] = quotient + 1; requiredSelectionsCount++; } } sort(requiredSelections, 0, requiredSelectionsCount); selectAllInPlace( requiredSelections, 0, requiredSelectionsCount - 1, dataset, 0, dataset.length - 1); Map ret = new LinkedHashMap<>(); for (int i = 0; i < indexes.length; i++) { int quotient = quotients[i]; int remainder = remainders[i]; if (remainder == 0) { ret.put(indexes[i], dataset[quotient]); } else { ret.put( indexes[i], interpolate(dataset[quotient], dataset[quotient + 1], remainder, scale)); } } return unmodifiableMap(ret); } } /** Returns whether any of the values in {@code dataset} are {@code NaN}. */ private static boolean containsNaN(double... dataset) { for (double value : dataset) { if (Double.isNaN(value)) { return true; } } return false; } /** * Returns a value a fraction {@code (remainder / scale)} of the way between {@code lower} and * {@code upper}. Assumes that {@code lower <= upper}. Correctly handles infinities (but not * {@code NaN}). */ private static double interpolate(double lower, double upper, double remainder, double scale) { if (lower == NEGATIVE_INFINITY) { if (upper == POSITIVE_INFINITY) { // Return NaN when lower == NEGATIVE_INFINITY and upper == POSITIVE_INFINITY: return NaN; } // Return NEGATIVE_INFINITY when NEGATIVE_INFINITY == lower <= upper < POSITIVE_INFINITY: return NEGATIVE_INFINITY; } if (upper == POSITIVE_INFINITY) { // Return POSITIVE_INFINITY when NEGATIVE_INFINITY < lower <= upper == POSITIVE_INFINITY: return POSITIVE_INFINITY; } return lower + (upper - lower) * remainder / scale; } private static void checkIndex(int index, int scale) { if (index < 0 || index > scale) { throw new IllegalArgumentException( "Quantile indexes must be between 0 and the scale, which is " + scale); } } private static double[] longsToDoubles(long[] longs) { int len = longs.length; double[] doubles = new double[len]; for (int i = 0; i < len; i++) { doubles[i] = longs[i]; } return doubles; } private static double[] intsToDoubles(int[] ints) { int len = ints.length; double[] doubles = new double[len]; for (int i = 0; i < len; i++) { doubles[i] = ints[i]; } return doubles; } /** * Performs an in-place selection to find the element which would appear at a given index in a * dataset if it were sorted. The following preconditions should hold: * *

    *
  • {@code required}, {@code from}, and {@code to} should all be indexes into {@code array}; *
  • {@code required} should be in the range [{@code from}, {@code to}]; *
  • all the values with indexes in the range [0, {@code from}) should be less than or equal * to all the values with indexes in the range [{@code from}, {@code to}]; *
  • all the values with indexes in the range ({@code to}, {@code array.length - 1}] should be * greater than or equal to all the values with indexes in the range [{@code from}, {@code * to}]. *
* * This method will reorder the values with indexes in the range [{@code from}, {@code to}] such * that all the values with indexes in the range [{@code from}, {@code required}) are less than or * equal to the value with index {@code required}, and all the values with indexes in the range * ({@code required}, {@code to}] are greater than or equal to that value. Therefore, the value at * {@code required} is the value which would appear at that index in the sorted dataset. */ private static void selectInPlace(int required, double[] array, int from, int to) { // If we are looking for the least element in the range, we can just do a linear search for it. // (We will hit this whenever we are doing quantile interpolation: our first selection finds // the lower value, our second one finds the upper value by looking for the next least element.) if (required == from) { int min = from; for (int index = from + 1; index <= to; index++) { if (array[min] > array[index]) { min = index; } } if (min != from) { swap(array, min, from); } return; } // Let's play quickselect! We'll repeatedly partition the range [from, to] containing the // required element, as long as it has more than one element. while (to > from) { int partitionPoint = partition(array, from, to); if (partitionPoint >= required) { to = partitionPoint - 1; } if (partitionPoint <= required) { from = partitionPoint + 1; } } } /** * Performs a partition operation on the slice of {@code array} with elements in the range [{@code * from}, {@code to}]. Uses the median of {@code from}, {@code to}, and the midpoint between them * as a pivot. Returns the index which the slice is partitioned around, i.e. if it returns {@code * ret} then we know that the values with indexes in [{@code from}, {@code ret}) are less than or * equal to the value at {@code ret} and the values with indexes in ({@code ret}, {@code to}] are * greater than or equal to that. */ private static int partition(double[] array, int from, int to) { // Select a pivot, and move it to the start of the slice i.e. to index from. movePivotToStartOfSlice(array, from, to); double pivot = array[from]; // Move all elements with indexes in (from, to] which are greater than the pivot to the end of // the array. Keep track of where those elements begin. int partitionPoint = to; for (int i = to; i > from; i--) { if (array[i] > pivot) { swap(array, partitionPoint, i); partitionPoint--; } } // We now know that all elements with indexes in (from, partitionPoint] are less than or equal // to the pivot at from, and all elements with indexes in (partitionPoint, to] are greater than // it. We swap the pivot into partitionPoint and we know the array is partitioned around that. swap(array, from, partitionPoint); return partitionPoint; } /** * Selects the pivot to use, namely the median of the values at {@code from}, {@code to}, and * halfway between the two (rounded down), from {@code array}, and ensure (by swapping elements if * necessary) that that pivot value appears at the start of the slice i.e. at {@code from}. * Expects that {@code from} is strictly less than {@code to}. */ private static void movePivotToStartOfSlice(double[] array, int from, int to) { int mid = (from + to) >>> 1; // We want to make a swap such that either array[to] <= array[from] <= array[mid], or // array[mid] <= array[from] <= array[to]. We know that from < to, so we know mid < to // (although it's possible that mid == from, if to == from + 1). Note that the postcondition // would be impossible to fulfil if mid == to unless we also have array[from] == array[to]. boolean toLessThanMid = (array[to] < array[mid]); boolean midLessThanFrom = (array[mid] < array[from]); boolean toLessThanFrom = (array[to] < array[from]); if (toLessThanMid == midLessThanFrom) { // Either array[to] < array[mid] < array[from] or array[from] <= array[mid] <= array[to]. swap(array, mid, from); } else if (toLessThanMid != toLessThanFrom) { // Either array[from] <= array[to] < array[mid] or array[mid] <= array[to] < array[from]. swap(array, from, to); } // The postcondition now holds. So the median, our chosen pivot, is at from. } /** * Performs an in-place selection, like {@link #selectInPlace}, to select all the indexes {@code * allRequired[i]} for {@code i} in the range [{@code requiredFrom}, {@code requiredTo}]. These * indexes must be sorted in the array and must all be in the range [{@code from}, {@code to}]. */ private static void selectAllInPlace( int[] allRequired, int requiredFrom, int requiredTo, double[] array, int from, int to) { // Choose the first selection to do... int requiredChosen = chooseNextSelection(allRequired, requiredFrom, requiredTo, from, to); int required = allRequired[requiredChosen]; // ...do the first selection... selectInPlace(required, array, from, to); // ...then recursively perform the selections in the range below... int requiredBelow = requiredChosen - 1; while (requiredBelow >= requiredFrom && allRequired[requiredBelow] == required) { requiredBelow--; // skip duplicates of required in the range below } if (requiredBelow >= requiredFrom) { selectAllInPlace(allRequired, requiredFrom, requiredBelow, array, from, required - 1); } // ...and then recursively perform the selections in the range above. int requiredAbove = requiredChosen + 1; while (requiredAbove <= requiredTo && allRequired[requiredAbove] == required) { requiredAbove++; // skip duplicates of required in the range above } if (requiredAbove <= requiredTo) { selectAllInPlace(allRequired, requiredAbove, requiredTo, array, required + 1, to); } } /** * Chooses the next selection to do from the required selections. It is required that the array * {@code allRequired} is sorted and that {@code allRequired[i]} are in the range [{@code from}, * {@code to}] for all {@code i} in the range [{@code requiredFrom}, {@code requiredTo}]. The * value returned by this method is the {@code i} in that range such that {@code allRequired[i]} * is as close as possible to the center of the range [{@code from}, {@code to}]. Choosing the * value closest to the center of the range first is the most efficient strategy because it * minimizes the size of the subranges from which the remaining selections must be done. */ private static int chooseNextSelection( int[] allRequired, int requiredFrom, int requiredTo, int from, int to) { if (requiredFrom == requiredTo) { return requiredFrom; // only one thing to choose, so choose it } // Find the center and round down. The true center is either centerFloor or halfway between // centerFloor and centerFloor + 1. int centerFloor = (from + to) >>> 1; // Do a binary search until we're down to the range of two which encloses centerFloor (unless // all values are lower or higher than centerFloor, in which case we find the two highest or // lowest respectively). If centerFloor is in allRequired, we will definitely find it. If not, // but centerFloor + 1 is, we'll definitely find that. The closest value to the true (unrounded) // center will be at either low or high. int low = requiredFrom; int high = requiredTo; while (high > low + 1) { int mid = (low + high) >>> 1; if (allRequired[mid] > centerFloor) { high = mid; } else if (allRequired[mid] < centerFloor) { low = mid; } else { return mid; // allRequired[mid] = centerFloor, so we can't get closer than that } } // Now pick the closest of the two candidates. Note that there is no rounding here. if (from + to - allRequired[low] - allRequired[high] > 0) { return high; } else { return low; } } /** Swaps the values at {@code i} and {@code j} in {@code array}. */ private static void swap(double[] array, int i, int j) { double temp = array[i]; array[i] = array[j]; array[j] = temp; } }




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