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/**
* Unit-API - Units of Measurement API for Java
* Copyright (c) 2005-2015, Jean-Marie Dautelle, Werner Keil, V2COM.
*
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution.
*
* 3. Neither the name of JSR-363 nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
* THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE,
* EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
package tec.units.ri;
import static tec.units.ri.unit.Units.ONE;
import java.util.Map;
import javax.measure.Dimension;
import javax.measure.Quantity;
import javax.measure.Unit;
import javax.measure.IncommensurableException;
import javax.measure.UnconvertibleException;
import javax.measure.UnitConverter;
import tec.units.ri.format.SimpleUnitFormat;
import tec.units.ri.format.EBNFUnitFormat;
import tec.units.ri.function.AddConverter;
import tec.units.ri.function.MultiplyConverter;
import tec.units.ri.function.RationalConverter;
import tec.units.ri.quantity.QuantityDimension;
import tec.units.ri.unit.AlternateUnit;
import tec.units.ri.unit.AnnotatedUnit;
import tec.units.ri.unit.ProductUnit;
import tec.units.ri.unit.TransformedUnit;
import tec.units.ri.unit.Units;
/**
*
* The class represents units founded on the seven SI base units for seven
* base quantities assumed to be mutually independent.
*
*
*
* For all physics units, units conversions are symmetrical:
* u1.getConverterTo(u2).equals(u2.getConverterTo(u1).inverse())
.
* Non-physical units (e.g. currency units) for which conversion is not
* symmetrical should have their own separate class hierarchy and are considered
* distinct (e.g. financial units), although they can always be combined with
* physics units (e.g. "€/Kg", "$/h").
*
*
* @author Jean-Marie Dautelle
* @author Werner Keil
* @version 0.9.1, Jul 5, 2015
*/
public abstract class AbstractUnit> implements Unit {
/**
*
*/
// private static final long serialVersionUID = -4344589505537030204L;
/**
* Holds the name.
*/
protected String name;
/**
* Holds the symbol.
*/
private String symbol;
/**
* Default constructor.
*/
protected AbstractUnit() {
}
/**
* Indicates if this unit belongs to the set of coherent SI units (unscaled
* SI units).
*
* The base and coherent derived units of the SI form a coherent set,
* designated the set of coherent SI units. The word coherent is used here
* in the following sense: when coherent units are used, equations between
* the numerical values of quantities take exactly the same form as the
* equations between the quantities themselves. Thus if only units from a
* coherent set are used, conversion factors between units are never
* required.
*
* @return equals(toSystemUnit())
*/
public boolean isSystemUnit() {
AbstractUnit si = this.toSystemUnit();
return (this == si) || this.equals(si);
}
/**
* Returns the unscaled standard (SI) unit from which this unit is derived.
*
* They SI unit can be be used to identify a quantity given the unit. For
* example: static boolean isAngularVelocity(AbstractUnit> unit) {
* return unit.toSystemUnit().equals(RADIAN.divide(SECOND)); }
* assert(REVOLUTION.divide(MINUTE).isAngularVelocity()); // Returns true.
*
*
* @return the unscaled metric unit from which this unit is derived.
*/
protected abstract AbstractUnit toSystemUnit();
/**
* Returns the converter from this unit to its unscaled {@link #toSystemUnit standard}
* unit.
*
* @return getConverterTo(this.toSystemUnit())
* @see #toSystemUnit
*/
public abstract UnitConverter getSystemConverter();
/**
* Annotates the specified unit. Annotation does not change the unit
* semantic. Annotations are often written between curly braces behind
* units. For example: Unit PERCENT_VOL =
* Units.PERCENT.annotate("vol"); // "%{vol}" AbstractUnit KG_TOTAL =
* Units.KILOGRAM.annotate("total"); // "kg{total}" AbstractUnit
* RED_BLOOD_CELLS = ONE.annotate("RBC"); // "{RBC}"
*
* Note: Annotations of system units are not considered themselves as system
* units.
*
* @param annotation
* the unit annotation.
* @return the annotated unit.
*/
public AnnotatedUnit annotate(String annotation) {
return new AnnotatedUnit(this, annotation);
}
/**
* Returns the physics unit represented by the specified characters.
*
* Locale-sensitive unit parsing may be handled using the OSGi
* {@link javax.measure.spi.UnitFormatService} or for non-OSGi applications
* instances of {@link SimpleUnitFormat}.
*
*
* Note: The standard UCUM format supports dimensionless units.[code]
* AbstractUnit PERCENT =
* AbstractUnit.parse("100").inverse().asType(Dimensionless.class); [/code]
*
*
* @param charSequence
* the character sequence to parse.
* @return SimpleUnitFormat.getInstance().parse(csq)
* @throws ParserException
* if the specified character sequence cannot be parsed correctly.
*/
public static Unit> parse(CharSequence charSequence) {
return EBNFUnitFormat.getInstance().parse(charSequence);
}
/**
* Returns the standard {@link String} representation of this unit. The string produced for a given unit
* is always the same; it is not affected by the locale. It can be used as a
* canonical string representation for exchanging units, or as a key for a
* Map, Hashtable, etc.
*
* Locale-sensitive unit parsing should be handled using the OSGi
* {@link tec.units.ri.SimpleUnitFormat.service.UnitFormat} service (or
* {@link SimpleUnitFormat} for non-OSGi applications).
*
* @return SimpleUnitFormat.getInstance().format(this)
*/
@Override
public String toString() {
return SimpleUnitFormat.getInstance().format(this);
/*
final Appendable tmp = new StringBuilder();
try {
return SimpleUnitFormat.getInstance().format(this, tmp).toString();
} catch (IOException ioException) {
throw new Error(ioException); // Should never happen.
} finally {
// if (tmp!=null) tmp.clear();
}
*/
}
// ///////////////////////////////////////////////////////
// Implements org.unitsofmeasurement.Unit interface //
// ///////////////////////////////////////////////////////
/**
* Returns the system unit (unscaled SI unit) from which this unit is
* derived. They can be be used to identify a quantity given the unit. For
* example:[code] static boolean isAngularVelocity(AbstractUnit> unit) {
* return unit.getSystemUnit().equals(RADIAN.divide(SECOND)); }
* assert(REVOLUTION.divide(MINUTE).isAngularVelocity()); // Returns true.
* [/code]
*
* @return the unscaled metric unit from which this unit is derived.
*/
@Override
public final AbstractUnit getSystemUnit() {
return toSystemUnit();
}
/**
* Indicates if this unit is compatible with the unit specified. To be
* compatible both units must be physics units having the same fundamental
* dimension.
*
* @param that
* the other unit.
* @return true
if this unit and that unit have equals
* fundamental dimension according to the current physics model;
* false
otherwise.
*/
@Override
public final boolean isCompatible(Unit> that) {
if ((this == that) || this.equals(that))
return true;
if (!(that instanceof AbstractUnit))
return false;
Dimension thisDimension = this.getDimension();
Dimension thatDimension = that.getDimension();
if (thisDimension.equals(thatDimension))
return true;
DimensionalModel model = DimensionalModel.current(); // Use
// dimensional
// analysis
// model.
return model.getFundamentalDimension(thisDimension).equals(
model.getFundamentalDimension(thatDimension));
}
/**
* Casts this unit to a parameterized unit of specified nature or throw a
* ClassCastException if the dimension of the specified quantity and this
* unit's dimension do not match (regardless whether or not the dimensions
* are independent or not).
*
* @param type
* the quantity class identifying the nature of the unit.
* @throws ClassCastException
* if the dimension of this unit is different from the
* SI dimension of the specified type.
* @see Units#getUnit(Class)
*/
@SuppressWarnings("unchecked")
@Override
public final > Unit asType(Class type) {
Dimension typeDimension = QuantityDimension.getInstance(type);
if ((typeDimension != null)
&& (!this.getDimension().equals(typeDimension)))
throw new ClassCastException("The unit: " + this
+ " is not compatible with quantities of type " + type);
return (Unit) this;
}
@Override
public abstract Map extends Unit>, Integer> getProductUnits();
@Override
public abstract Dimension getDimension();
protected void setName(String name) {
this.name = name;
}
public String getName() {
return name;
}
public String getSymbol() {
return symbol;
}
protected void setSymbol(String s) {
this.symbol = s;
}
@Override
public final UnitConverter getConverterTo(Unit that)
throws UnconvertibleException {
if ((this == that) || this.equals(that))
return AbstractConverter.IDENTITY; // Shortcut.
Unit thisSystemUnit = this.getSystemUnit();
Unit thatSystemUnit = that.getSystemUnit();
if (!thisSystemUnit.equals(thatSystemUnit))
try {
return getConverterToAny(that);
} catch (IncommensurableException e) {
throw new UnconvertibleException(e);
}
UnitConverter thisToSI = this.getSystemConverter();
UnitConverter thatToSI = that.getConverterTo(thatSystemUnit);
return thatToSI.inverse().concatenate(thisToSI);
}
@SuppressWarnings("rawtypes")
@Override
public final UnitConverter getConverterToAny(Unit> that)
throws IncommensurableException, UnconvertibleException {
if (!isCompatible(that))
throw new IncommensurableException(this
+ " is not compatible with " + that);
AbstractUnit thatAbstr = (AbstractUnit) that; // Since both units are
// compatible they must
// be both abstract
// units.
DimensionalModel model = DimensionalModel.current();
AbstractUnit thisSystemUnit = this.getSystemUnit();
UnitConverter thisToDimension = model.getDimensionalTransform(
thisSystemUnit.getDimension()).concatenate(
this.getSystemConverter());
AbstractUnit thatSystemUnit = thatAbstr.getSystemUnit();
UnitConverter thatToDimension = model.getDimensionalTransform(
thatSystemUnit.getDimension()).concatenate(
thatAbstr.getSystemConverter());
return thatToDimension.inverse().concatenate(thisToDimension);
}
@Override
public final Unit alternate(String symbol) {
return new AlternateUnit(this, symbol);
}
@Override
public final AbstractUnit transform(UnitConverter operation) {
AbstractUnit systemUnit = this.getSystemUnit();
UnitConverter cvtr = this.getSystemConverter().concatenate(operation);
if (cvtr.equals(AbstractConverter.IDENTITY))
return systemUnit;
return new TransformedUnit(systemUnit, cvtr);
}
@Override
public final AbstractUnit shift(double offset) {
if (offset == 0)
return this;
return transform(new AddConverter(offset));
}
@Override
public final AbstractUnit multiply(double factor) {
if (factor == 1)
return this;
if (isLongValue(factor))
return transform(new RationalConverter((long) factor, 1));
return transform(new MultiplyConverter(factor));
}
private static boolean isLongValue(double value) {
return !((value < Long.MIN_VALUE) || (value > Long.MAX_VALUE))
&& Math.floor(value) == value;
}
/**
* Returns the product of this unit with the one specified.
*
*
* Note: If the specified unit (that) is not a physical unit, then
* that.multiply(this)
is returned.
*
*
* @param that
* the unit multiplicand.
* @return this * that
*/
@Override
public final Unit> multiply(Unit> that) {
if (that instanceof AbstractUnit)
return multiply((AbstractUnit>) that);
return that.multiply(this); // Commutatif.
}
/**
* Returns the product of this physical unit with the one specified.
*
* @param that
* the physical unit multiplicand.
* @return this * that
*/
public final Unit> multiply(AbstractUnit> that) {
if (this.equals(ONE))
return that;
if (that.equals(ONE))
return this;
return ProductUnit.getProductInstance(this, that);
}
/**
* Returns the inverse of this physical unit.
*
* @return 1 / this
*/
@Override
public final Unit> inverse() {
if (this.equals(ONE))
return this;
return ProductUnit.getQuotientInstance(ONE, this);
}
/**
* Returns the result of dividing this unit by the specifified divisor. If
* the factor is an integer value, the division is exact. For example:
*
*
*
* QUART = GALLON_LIQUID_US.divide(4); // Exact definition.
*
*
*
* @param divisor
* the divisor value.
* @return this unit divided by the specified divisor.
*/
@Override
public final AbstractUnit divide(double divisor) {
if (divisor == 1)
return this;
if (isLongValue(divisor))
return transform(new RationalConverter(1, (long) divisor));
return transform(new MultiplyConverter(1.0 / divisor));
}
/**
* Returns the quotient of this unit with the one specified.
*
* @param that
* the unit divisor.
* @return this.multiply(that.inverse())
*/
@Override
public final Unit> divide(Unit> that) {
return this.multiply(that.inverse());
}
/**
* Returns a unit equals to the given root of this unit.
*
* @param n
* the root's order.
* @return the result of taking the given root of this unit.
* @throws ArithmeticException
* if n == 0
or if this operation would result in
* an unit with a fractional exponent.
*/
@Override
public final Unit> root(int n) {
if (n > 0)
return ProductUnit.getRootInstance(this, n);
else if (n == 0)
throw new ArithmeticException("Root's order of zero");
else
// n < 0
return ONE.divide(this.root(-n));
}
/**
* Returns a unit equals to this unit raised to an exponent.
*
* @param n
* the exponent.
* @return the result of raising this unit to the exponent.
*/
@Override
public final Unit> pow(int n) {
if (n > 0)
return this.multiply(this.pow(n - 1));
else if (n == 0)
return ONE;
else
// n < 0
return ONE.divide(this.pow(-n));
}
// //////////////////////////////////////////////////////////////
// Ensures that sub-classes implements hashCode/equals method.
// //////////////////////////////////////////////////////////////
@Override
public abstract int hashCode();
@Override
public abstract boolean equals(Object that);
}