diff options
Diffstat (limited to 'src/main/java/org/apache/commons/math/dfp/DfpField.java')
-rw-r--r-- | src/main/java/org/apache/commons/math/dfp/DfpField.java | 750 |
1 files changed, 750 insertions, 0 deletions
diff --git a/src/main/java/org/apache/commons/math/dfp/DfpField.java b/src/main/java/org/apache/commons/math/dfp/DfpField.java new file mode 100644 index 0000000..65a25f4 --- /dev/null +++ b/src/main/java/org/apache/commons/math/dfp/DfpField.java @@ -0,0 +1,750 @@ +/* + * 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.math.dfp; + +import org.apache.commons.math.Field; + +/** Field for Decimal floating point instances. + * @version $Revision: 995987 $ $Date: 2010-09-10 23:24:15 +0200 (ven. 10 sept. 2010) $ + * @since 2.2 + */ +public class DfpField implements Field<Dfp> { + + /** Enumerate for rounding modes. */ + public enum RoundingMode { + + /** Rounds toward zero (truncation). */ + ROUND_DOWN, + + /** Rounds away from zero if discarded digit is non-zero. */ + ROUND_UP, + + /** Rounds towards nearest unless both are equidistant in which case it rounds away from zero. */ + ROUND_HALF_UP, + + /** Rounds towards nearest unless both are equidistant in which case it rounds toward zero. */ + ROUND_HALF_DOWN, + + /** Rounds towards nearest unless both are equidistant in which case it rounds toward the even neighbor. + * This is the default as specified by IEEE 854-1987 + */ + ROUND_HALF_EVEN, + + /** Rounds towards nearest unless both are equidistant in which case it rounds toward the odd neighbor. */ + ROUND_HALF_ODD, + + /** Rounds towards positive infinity. */ + ROUND_CEIL, + + /** Rounds towards negative infinity. */ + ROUND_FLOOR; + + } + + /** IEEE 854-1987 flag for invalid operation. */ + public static final int FLAG_INVALID = 1; + + /** IEEE 854-1987 flag for division by zero. */ + public static final int FLAG_DIV_ZERO = 2; + + /** IEEE 854-1987 flag for overflow. */ + public static final int FLAG_OVERFLOW = 4; + + /** IEEE 854-1987 flag for underflow. */ + public static final int FLAG_UNDERFLOW = 8; + + /** IEEE 854-1987 flag for inexact result. */ + public static final int FLAG_INEXACT = 16; + + /** High precision string representation of √2. */ + private static String sqr2String; + + /** High precision string representation of √2 / 2. */ + private static String sqr2ReciprocalString; + + /** High precision string representation of √3. */ + private static String sqr3String; + + /** High precision string representation of √3 / 3. */ + private static String sqr3ReciprocalString; + + /** High precision string representation of π. */ + private static String piString; + + /** High precision string representation of e. */ + private static String eString; + + /** High precision string representation of ln(2). */ + private static String ln2String; + + /** High precision string representation of ln(5). */ + private static String ln5String; + + /** High precision string representation of ln(10). */ + private static String ln10String; + + /** The number of radix digits. + * Note these depend on the radix which is 10000 digits, + * so each one is equivalent to 4 decimal digits. + */ + private final int radixDigits; + + /** A {@link Dfp} with value 0. */ + private final Dfp zero; + + /** A {@link Dfp} with value 1. */ + private final Dfp one; + + /** A {@link Dfp} with value 2. */ + private final Dfp two; + + /** A {@link Dfp} with value √2. */ + private final Dfp sqr2; + + /** A two elements {@link Dfp} array with value √2 split in two pieces. */ + private final Dfp[] sqr2Split; + + /** A {@link Dfp} with value √2 / 2. */ + private final Dfp sqr2Reciprocal; + + /** A {@link Dfp} with value √3. */ + private final Dfp sqr3; + + /** A {@link Dfp} with value √3 / 3. */ + private final Dfp sqr3Reciprocal; + + /** A {@link Dfp} with value π. */ + private final Dfp pi; + + /** A two elements {@link Dfp} array with value π split in two pieces. */ + private final Dfp[] piSplit; + + /** A {@link Dfp} with value e. */ + private final Dfp e; + + /** A two elements {@link Dfp} array with value e split in two pieces. */ + private final Dfp[] eSplit; + + /** A {@link Dfp} with value ln(2). */ + private final Dfp ln2; + + /** A two elements {@link Dfp} array with value ln(2) split in two pieces. */ + private final Dfp[] ln2Split; + + /** A {@link Dfp} with value ln(5). */ + private final Dfp ln5; + + /** A two elements {@link Dfp} array with value ln(5) split in two pieces. */ + private final Dfp[] ln5Split; + + /** A {@link Dfp} with value ln(10). */ + private final Dfp ln10; + + /** Current rounding mode. */ + private RoundingMode rMode; + + /** IEEE 854-1987 signals. */ + private int ieeeFlags; + + /** Create a factory for the specified number of radix digits. + * <p> + * Note that since the {@link Dfp} class uses 10000 as its radix, each radix + * digit is equivalent to 4 decimal digits. This implies that asking for + * 13, 14, 15 or 16 decimal digits will really lead to a 4 radix 10000 digits in + * all cases. + * </p> + * @param decimalDigits minimal number of decimal digits. + */ + public DfpField(final int decimalDigits) { + this(decimalDigits, true); + } + + /** Create a factory for the specified number of radix digits. + * <p> + * Note that since the {@link Dfp} class uses 10000 as its radix, each radix + * digit is equivalent to 4 decimal digits. This implies that asking for + * 13, 14, 15 or 16 decimal digits will really lead to a 4 radix 10000 digits in + * all cases. + * </p> + * @param decimalDigits minimal number of decimal digits + * @param computeConstants if true, the transcendental constants for the given precision + * must be computed (setting this flag to false is RESERVED for the internal recursive call) + */ + private DfpField(final int decimalDigits, final boolean computeConstants) { + + this.radixDigits = (decimalDigits < 13) ? 4 : (decimalDigits + 3) / 4; + this.rMode = RoundingMode.ROUND_HALF_EVEN; + this.ieeeFlags = 0; + this.zero = new Dfp(this, 0); + this.one = new Dfp(this, 1); + this.two = new Dfp(this, 2); + + if (computeConstants) { + // set up transcendental constants + synchronized (DfpField.class) { + + // as a heuristic to circumvent Table-Maker's Dilemma, we set the string + // representation of the constants to be at least 3 times larger than the + // number of decimal digits, also as an attempt to really compute these + // constants only once, we set a minimum number of digits + computeStringConstants((decimalDigits < 67) ? 200 : (3 * decimalDigits)); + + // set up the constants at current field accuracy + sqr2 = new Dfp(this, sqr2String); + sqr2Split = split(sqr2String); + sqr2Reciprocal = new Dfp(this, sqr2ReciprocalString); + sqr3 = new Dfp(this, sqr3String); + sqr3Reciprocal = new Dfp(this, sqr3ReciprocalString); + pi = new Dfp(this, piString); + piSplit = split(piString); + e = new Dfp(this, eString); + eSplit = split(eString); + ln2 = new Dfp(this, ln2String); + ln2Split = split(ln2String); + ln5 = new Dfp(this, ln5String); + ln5Split = split(ln5String); + ln10 = new Dfp(this, ln10String); + + } + } else { + // dummy settings for unused constants + sqr2 = null; + sqr2Split = null; + sqr2Reciprocal = null; + sqr3 = null; + sqr3Reciprocal = null; + pi = null; + piSplit = null; + e = null; + eSplit = null; + ln2 = null; + ln2Split = null; + ln5 = null; + ln5Split = null; + ln10 = null; + } + + } + + /** Get the number of radix digits of the {@link Dfp} instances built by this factory. + * @return number of radix digits + */ + public int getRadixDigits() { + return radixDigits; + } + + /** Set the rounding mode. + * If not set, the default value is {@link RoundingMode#ROUND_HALF_EVEN}. + * @param mode desired rounding mode + * Note that the rounding mode is common to all {@link Dfp} instances + * belonging to the current {@link DfpField} in the system and will + * affect all future calculations. + */ + public void setRoundingMode(final RoundingMode mode) { + rMode = mode; + } + + /** Get the current rounding mode. + * @return current rounding mode + */ + public RoundingMode getRoundingMode() { + return rMode; + } + + /** Get the IEEE 854 status flags. + * @return IEEE 854 status flags + * @see #clearIEEEFlags() + * @see #setIEEEFlags(int) + * @see #setIEEEFlagsBits(int) + * @see #FLAG_INVALID + * @see #FLAG_DIV_ZERO + * @see #FLAG_OVERFLOW + * @see #FLAG_UNDERFLOW + * @see #FLAG_INEXACT + */ + public int getIEEEFlags() { + return ieeeFlags; + } + + /** Clears the IEEE 854 status flags. + * @see #getIEEEFlags() + * @see #setIEEEFlags(int) + * @see #setIEEEFlagsBits(int) + * @see #FLAG_INVALID + * @see #FLAG_DIV_ZERO + * @see #FLAG_OVERFLOW + * @see #FLAG_UNDERFLOW + * @see #FLAG_INEXACT + */ + public void clearIEEEFlags() { + ieeeFlags = 0; + } + + /** Sets the IEEE 854 status flags. + * @param flags desired value for the flags + * @see #getIEEEFlags() + * @see #clearIEEEFlags() + * @see #setIEEEFlagsBits(int) + * @see #FLAG_INVALID + * @see #FLAG_DIV_ZERO + * @see #FLAG_OVERFLOW + * @see #FLAG_UNDERFLOW + * @see #FLAG_INEXACT + */ + public void setIEEEFlags(final int flags) { + ieeeFlags = flags & (FLAG_INVALID | FLAG_DIV_ZERO | FLAG_OVERFLOW | FLAG_UNDERFLOW | FLAG_INEXACT); + } + + /** Sets some bits in the IEEE 854 status flags, without changing the already set bits. + * <p> + * Calling this method is equivalent to call {@code setIEEEFlags(getIEEEFlags() | bits)} + * </p> + * @param bits bits to set + * @see #getIEEEFlags() + * @see #clearIEEEFlags() + * @see #setIEEEFlags(int) + * @see #FLAG_INVALID + * @see #FLAG_DIV_ZERO + * @see #FLAG_OVERFLOW + * @see #FLAG_UNDERFLOW + * @see #FLAG_INEXACT + */ + public void setIEEEFlagsBits(final int bits) { + ieeeFlags |= bits & (FLAG_INVALID | FLAG_DIV_ZERO | FLAG_OVERFLOW | FLAG_UNDERFLOW | FLAG_INEXACT); + } + + /** Makes a {@link Dfp} with a value of 0. + * @return a new {@link Dfp} with a value of 0 + */ + public Dfp newDfp() { + return new Dfp(this); + } + + /** Create an instance from a byte value. + * @param x value to convert to an instance + * @return a new {@link Dfp} with the same value as x + */ + public Dfp newDfp(final byte x) { + return new Dfp(this, x); + } + + /** Create an instance from an int value. + * @param x value to convert to an instance + * @return a new {@link Dfp} with the same value as x + */ + public Dfp newDfp(final int x) { + return new Dfp(this, x); + } + + /** Create an instance from a long value. + * @param x value to convert to an instance + * @return a new {@link Dfp} with the same value as x + */ + public Dfp newDfp(final long x) { + return new Dfp(this, x); + } + + /** Create an instance from a double value. + * @param x value to convert to an instance + * @return a new {@link Dfp} with the same value as x + */ + public Dfp newDfp(final double x) { + return new Dfp(this, x); + } + + /** Copy constructor. + * @param d instance to copy + * @return a new {@link Dfp} with the same value as d + */ + public Dfp newDfp(Dfp d) { + return new Dfp(d); + } + + /** Create a {@link Dfp} given a String representation. + * @param s string representation of the instance + * @return a new {@link Dfp} parsed from specified string + */ + public Dfp newDfp(final String s) { + return new Dfp(this, s); + } + + /** Creates a {@link Dfp} with a non-finite value. + * @param sign sign of the Dfp to create + * @param nans code of the value, must be one of {@link Dfp#INFINITE}, + * {@link Dfp#SNAN}, {@link Dfp#QNAN} + * @return a new {@link Dfp} with a non-finite value + */ + public Dfp newDfp(final byte sign, final byte nans) { + return new Dfp(this, sign, nans); + } + + /** Get the constant 0. + * @return a {@link Dfp} with value 0 + */ + public Dfp getZero() { + return zero; + } + + /** Get the constant 1. + * @return a {@link Dfp} with value 1 + */ + public Dfp getOne() { + return one; + } + + /** Get the constant 2. + * @return a {@link Dfp} with value 2 + */ + public Dfp getTwo() { + return two; + } + + /** Get the constant √2. + * @return a {@link Dfp} with value √2 + */ + public Dfp getSqr2() { + return sqr2; + } + + /** Get the constant √2 split in two pieces. + * @return a {@link Dfp} with value √2 split in two pieces + */ + public Dfp[] getSqr2Split() { + return sqr2Split.clone(); + } + + /** Get the constant √2 / 2. + * @return a {@link Dfp} with value √2 / 2 + */ + public Dfp getSqr2Reciprocal() { + return sqr2Reciprocal; + } + + /** Get the constant √3. + * @return a {@link Dfp} with value √3 + */ + public Dfp getSqr3() { + return sqr3; + } + + /** Get the constant √3 / 3. + * @return a {@link Dfp} with value √3 / 3 + */ + public Dfp getSqr3Reciprocal() { + return sqr3Reciprocal; + } + + /** Get the constant π. + * @return a {@link Dfp} with value π + */ + public Dfp getPi() { + return pi; + } + + /** Get the constant π split in two pieces. + * @return a {@link Dfp} with value π split in two pieces + */ + public Dfp[] getPiSplit() { + return piSplit.clone(); + } + + /** Get the constant e. + * @return a {@link Dfp} with value e + */ + public Dfp getE() { + return e; + } + + /** Get the constant e split in two pieces. + * @return a {@link Dfp} with value e split in two pieces + */ + public Dfp[] getESplit() { + return eSplit.clone(); + } + + /** Get the constant ln(2). + * @return a {@link Dfp} with value ln(2) + */ + public Dfp getLn2() { + return ln2; + } + + /** Get the constant ln(2) split in two pieces. + * @return a {@link Dfp} with value ln(2) split in two pieces + */ + public Dfp[] getLn2Split() { + return ln2Split.clone(); + } + + /** Get the constant ln(5). + * @return a {@link Dfp} with value ln(5) + */ + public Dfp getLn5() { + return ln5; + } + + /** Get the constant ln(5) split in two pieces. + * @return a {@link Dfp} with value ln(5) split in two pieces + */ + public Dfp[] getLn5Split() { + return ln5Split.clone(); + } + + /** Get the constant ln(10). + * @return a {@link Dfp} with value ln(10) + */ + public Dfp getLn10() { + return ln10; + } + + /** Breaks a string representation up into two {@link Dfp}'s. + * The split is such that the sum of them is equivalent to the input string, + * but has higher precision than using a single Dfp. + * @param a string representation of the number to split + * @return an array of two {@link Dfp Dfp} instances which sum equals a + */ + private Dfp[] split(final String a) { + Dfp result[] = new Dfp[2]; + boolean leading = true; + int sp = 0; + int sig = 0; + + char[] buf = new char[a.length()]; + + for (int i = 0; i < buf.length; i++) { + buf[i] = a.charAt(i); + + if (buf[i] >= '1' && buf[i] <= '9') { + leading = false; + } + + if (buf[i] == '.') { + sig += (400 - sig) % 4; + leading = false; + } + + if (sig == (radixDigits / 2) * 4) { + sp = i; + break; + } + + if (buf[i] >= '0' && buf[i] <= '9' && !leading) { + sig ++; + } + } + + result[0] = new Dfp(this, new String(buf, 0, sp)); + + for (int i = 0; i < buf.length; i++) { + buf[i] = a.charAt(i); + if (buf[i] >= '0' && buf[i] <= '9' && i < sp) { + buf[i] = '0'; + } + } + + result[1] = new Dfp(this, new String(buf)); + + return result; + + } + + /** Recompute the high precision string constants. + * @param highPrecisionDecimalDigits precision at which the string constants mus be computed + */ + private static void computeStringConstants(final int highPrecisionDecimalDigits) { + if (sqr2String == null || sqr2String.length() < highPrecisionDecimalDigits - 3) { + + // recompute the string representation of the transcendental constants + final DfpField highPrecisionField = new DfpField(highPrecisionDecimalDigits, false); + final Dfp highPrecisionOne = new Dfp(highPrecisionField, 1); + final Dfp highPrecisionTwo = new Dfp(highPrecisionField, 2); + final Dfp highPrecisionThree = new Dfp(highPrecisionField, 3); + + final Dfp highPrecisionSqr2 = highPrecisionTwo.sqrt(); + sqr2String = highPrecisionSqr2.toString(); + sqr2ReciprocalString = highPrecisionOne.divide(highPrecisionSqr2).toString(); + + final Dfp highPrecisionSqr3 = highPrecisionThree.sqrt(); + sqr3String = highPrecisionSqr3.toString(); + sqr3ReciprocalString = highPrecisionOne.divide(highPrecisionSqr3).toString(); + + piString = computePi(highPrecisionOne, highPrecisionTwo, highPrecisionThree).toString(); + eString = computeExp(highPrecisionOne, highPrecisionOne).toString(); + ln2String = computeLn(highPrecisionTwo, highPrecisionOne, highPrecisionTwo).toString(); + ln5String = computeLn(new Dfp(highPrecisionField, 5), highPrecisionOne, highPrecisionTwo).toString(); + ln10String = computeLn(new Dfp(highPrecisionField, 10), highPrecisionOne, highPrecisionTwo).toString(); + + } + } + + /** Compute π using Jonathan and Peter Borwein quartic formula. + * @param one constant with value 1 at desired precision + * @param two constant with value 2 at desired precision + * @param three constant with value 3 at desired precision + * @return π + */ + private static Dfp computePi(final Dfp one, final Dfp two, final Dfp three) { + + Dfp sqrt2 = two.sqrt(); + Dfp yk = sqrt2.subtract(one); + Dfp four = two.add(two); + Dfp two2kp3 = two; + Dfp ak = two.multiply(three.subtract(two.multiply(sqrt2))); + + // The formula converges quartically. This means the number of correct + // digits is multiplied by 4 at each iteration! Five iterations are + // sufficient for about 160 digits, eight iterations give about + // 10000 digits (this has been checked) and 20 iterations more than + // 160 billions of digits (this has NOT been checked). + // So the limit here is considered sufficient for most purposes ... + for (int i = 1; i < 20; i++) { + final Dfp ykM1 = yk; + + final Dfp y2 = yk.multiply(yk); + final Dfp oneMinusY4 = one.subtract(y2.multiply(y2)); + final Dfp s = oneMinusY4.sqrt().sqrt(); + yk = one.subtract(s).divide(one.add(s)); + + two2kp3 = two2kp3.multiply(four); + + final Dfp p = one.add(yk); + final Dfp p2 = p.multiply(p); + ak = ak.multiply(p2.multiply(p2)).subtract(two2kp3.multiply(yk).multiply(one.add(yk).add(yk.multiply(yk)))); + + if (yk.equals(ykM1)) { + break; + } + } + + return one.divide(ak); + + } + + /** Compute exp(a). + * @param a number for which we want the exponential + * @param one constant with value 1 at desired precision + * @return exp(a) + */ + public static Dfp computeExp(final Dfp a, final Dfp one) { + + Dfp y = new Dfp(one); + Dfp py = new Dfp(one); + Dfp f = new Dfp(one); + Dfp fi = new Dfp(one); + Dfp x = new Dfp(one); + + for (int i = 0; i < 10000; i++) { + x = x.multiply(a); + y = y.add(x.divide(f)); + fi = fi.add(one); + f = f.multiply(fi); + if (y.equals(py)) { + break; + } + py = new Dfp(y); + } + + return y; + + } + + + /** Compute ln(a). + * + * Let f(x) = ln(x), + * + * We know that f'(x) = 1/x, thus from Taylor's theorem we have: + * + * ----- n+1 n + * f(x) = \ (-1) (x - 1) + * / ---------------- for 1 <= n <= infinity + * ----- n + * + * or + * 2 3 4 + * (x-1) (x-1) (x-1) + * ln(x) = (x-1) - ----- + ------ - ------ + ... + * 2 3 4 + * + * alternatively, + * + * 2 3 4 + * x x x + * ln(x+1) = x - - + - - - + ... + * 2 3 4 + * + * This series can be used to compute ln(x), but it converges too slowly. + * + * If we substitute -x for x above, we get + * + * 2 3 4 + * x x x + * ln(1-x) = -x - - - - - - + ... + * 2 3 4 + * + * Note that all terms are now negative. Because the even powered ones + * absorbed the sign. Now, subtract the series above from the previous + * one to get ln(x+1) - ln(1-x). Note the even terms cancel out leaving + * only the odd ones + * + * 3 5 7 + * 2x 2x 2x + * ln(x+1) - ln(x-1) = 2x + --- + --- + ---- + ... + * 3 5 7 + * + * By the property of logarithms that ln(a) - ln(b) = ln (a/b) we have: + * + * 3 5 7 + * x+1 / x x x \ + * ln ----- = 2 * | x + ---- + ---- + ---- + ... | + * x-1 \ 3 5 7 / + * + * But now we want to find ln(a), so we need to find the value of x + * such that a = (x+1)/(x-1). This is easily solved to find that + * x = (a-1)/(a+1). + * @param a number for which we want the exponential + * @param one constant with value 1 at desired precision + * @param two constant with value 2 at desired precision + * @return ln(a) + */ + + public static Dfp computeLn(final Dfp a, final Dfp one, final Dfp two) { + + int den = 1; + Dfp x = a.add(new Dfp(a.getField(), -1)).divide(a.add(one)); + + Dfp y = new Dfp(x); + Dfp num = new Dfp(x); + Dfp py = new Dfp(y); + for (int i = 0; i < 10000; i++) { + num = num.multiply(x); + num = num.multiply(x); + den = den + 2; + Dfp t = num.divide(den); + y = y.add(t); + if (y.equals(py)) { + break; + } + py = new Dfp(y); + } + + return y.multiply(two); + + } + +} |