package org.djunits.value.vfloat.scalar;
   
   import java.util.Locale;
   
   import org.djunits.unit.DensityUnit;
   import org.djunits.unit.DimensionlessUnit;
   import org.djunits.unit.FlowMassUnit;
   import org.djunits.unit.FlowVolumeUnit;
   import org.djunits.unit.ForceUnit;
  import org.djunits.unit.FrequencyUnit;
  import org.djunits.unit.MassUnit;
  import org.djunits.unit.MomentumUnit;
  import org.djunits.value.vfloat.scalar.base.FloatScalarRel;
  import org.djutils.base.NumberParser;
  import org.djutils.exceptions.Throw;
  
  import jakarta.annotation.Generated;
  
  /**
   * Easy access methods for the FloatFlowMass FloatScalar, which is relative by definition.
   * <p>
   * Copyright (c) 2013-2025 Delft University of Technology, PO Box 5, 2600 AA, Delft, the Netherlands. All rights reserved. <br>
   * BSD-style license. See <a href="https://djunits.org/docs/license.html">DJUNITS License</a>.
   * </p>
   * @author <a href="https://www.tudelft.nl/averbraeck">Alexander Verbraeck</a>
   * @author <a href="https://www.tudelft.nl/staff/p.knoppers/">Peter Knoppers</a>
   */
  @Generated(value = "org.djunits.generator.GenerateDJUNIT", date = "2025-09-06T15:16:28.380798Z")
  public class FloatFlowMass extends FloatScalarRel<FlowMassUnit, FloatFlowMass>
  {
      /** */
      private static final long serialVersionUID = 20150901L;
  
      /** Constant with value zero. */
      public static final FloatFlowMass ZERO = new FloatFlowMass(0.0f, FlowMassUnit.SI);
  
      /** Constant with value one. */
      public static final FloatFlowMass ONE = new FloatFlowMass(1.0f, FlowMassUnit.SI);
  
      /** Constant with value NaN. */
      @SuppressWarnings("checkstyle:constantname")
      public static final FloatFlowMass NaN = new FloatFlowMass(Float.NaN, FlowMassUnit.SI);
  
      /** Constant with value POSITIVE_INFINITY. */
      public static final FloatFlowMass POSITIVE_INFINITY = new FloatFlowMass(Float.POSITIVE_INFINITY, FlowMassUnit.SI);
  
      /** Constant with value NEGATIVE_INFINITY. */
      public static final FloatFlowMass NEGATIVE_INFINITY = new FloatFlowMass(Float.NEGATIVE_INFINITY, FlowMassUnit.SI);
  
      /** Constant with value MAX_VALUE. */
      public static final FloatFlowMass POS_MAXVALUE = new FloatFlowMass(Float.MAX_VALUE, FlowMassUnit.SI);
  
      /** Constant with value -MAX_VALUE. */
      public static final FloatFlowMass NEG_MAXVALUE = new FloatFlowMass(-Float.MAX_VALUE, FlowMassUnit.SI);
  
      /**
       * Construct FloatFlowMass scalar with a unit.
       * @param value the float value, expressed in the given unit
       * @param unit unit for the float value
       */
      public FloatFlowMass(final float value, final FlowMassUnit unit)
      {
          super(value, unit);
      }
  
      /**
       * Construct FloatFlowMass scalar.
       * @param value Scalar from which to construct this instance
       */
      public FloatFlowMass(final FloatFlowMass value)
      {
          super(value);
      }
  
      /**
       * Construct FloatFlowMass scalar with a unit using a double value.
       * @param value the double value, expressed in the given unit
       * @param unit unit for the resulting float value
       */
      public FloatFlowMass(final double value, final FlowMassUnit unit)
      {
          super((float) value, unit);
      }
  
      @Override
      public final FloatFlowMass instantiateRel(final float value, final FlowMassUnit unit)
      {
          return new FloatFlowMass(value, unit);
      }
  
      /**
       * Construct FloatFlowMass scalar based on an SI value.
       * @param value the float value in SI units
       * @return the new scalar with the SI value
       */
      public static final FloatFlowMass ofSI(final float value)
      {
          return new FloatFlowMass(value, FlowMassUnit.SI);
      }
 
     /**
      * Interpolate between two values. Note that the first value does not have to be smaller than the second.
      * @param zero the value at a ratio of zero
      * @param one the value at a ratio of one
      * @param ratio the ratio between 0 and 1, inclusive
      * @return a FloatFlowMass at the given ratio between 0 and 1
      */
     public static FloatFlowMass interpolate(final FloatFlowMass zero, final FloatFlowMass one, final float ratio)
     {
         Throw.when(ratio < 0.0 || ratio > 1.0, IllegalArgumentException.class,
                 "ratio for interpolation should be between 0 and 1, but is %f", ratio);
         return new FloatFlowMass(zero.getInUnit() * (1 - ratio) + one.getInUnit(zero.getDisplayUnit()) * ratio,
                 zero.getDisplayUnit());
     }
 
     /**
      * Return the maximum value of two relative scalars.
      * @param r1 the first scalar
      * @param r2 the second scalar
      * @return the maximum value of two relative scalars
      */
     public static FloatFlowMass max(final FloatFlowMass r1, final FloatFlowMass r2)
     {
         return r1.gt(r2) ? r1 : r2;
     }
 
     /**
      * Return the maximum value of more than two relative scalars.
      * @param r1 the first scalar
      * @param r2 the second scalar
      * @param rn the other scalars
      * @return the maximum value of more than two relative scalars
      */
     public static FloatFlowMass max(final FloatFlowMass r1, final FloatFlowMass r2, final FloatFlowMass... rn)
     {
         FloatFlowMass maxr = r1.gt(r2) ? r1 : r2;
         for (FloatFlowMass r : rn)
         {
             if (r.gt(maxr))
             {
                 maxr = r;
             }
         }
         return maxr;
     }
 
     /**
      * Return the minimum value of two relative scalars.
      * @param r1 the first scalar
      * @param r2 the second scalar
      * @return the minimum value of two relative scalars
      */
     public static FloatFlowMass min(final FloatFlowMass r1, final FloatFlowMass r2)
     {
         return r1.lt(r2) ? r1 : r2;
     }
 
     /**
      * Return the minimum value of more than two relative scalars.
      * @param r1 the first scalar
      * @param r2 the second scalar
      * @param rn the other scalars
      * @return the minimum value of more than two relative scalars
      */
     public static FloatFlowMass min(final FloatFlowMass r1, final FloatFlowMass r2, final FloatFlowMass... rn)
     {
         FloatFlowMass minr = r1.lt(r2) ? r1 : r2;
         for (FloatFlowMass r : rn)
         {
             if (r.lt(minr))
             {
                 minr = r;
             }
         }
         return minr;
     }
 
     /**
      * Returns a FloatFlowMass representation of a textual representation of a value with a unit. The String representation that
      * can be parsed is the double value in the unit, followed by a localized or English abbreviation of the unit. Spaces are
      * allowed, but not required, between the value and the unit.
      * @param text the textual representation to parse into a FloatFlowMass
      * @return the Scalar representation of the value in its unit
      * @throws IllegalArgumentException when the text cannot be parsed
      * @throws NullPointerException when the text argument is null
      */
     public static FloatFlowMass valueOf(final String text)
     {
         Throw.whenNull(text, "Error parsing FloatFlowMass: text to parse is null");
         Throw.when(text.length() == 0, IllegalArgumentException.class, "Error parsing FloatFlowMass: empty text to parse");
         try
         {
             NumberParser numberParser = new NumberParser().lenient().trailing();
             float f = numberParser.parseFloat(text);
             String unitString = text.substring(numberParser.getTrailingPosition()).trim();
             FlowMassUnit unit = FlowMassUnit.BASE.getUnitByAbbreviation(unitString);
             Throw.when(unit == null, IllegalArgumentException.class, "Unit %s not found for quantity FlowMass", unitString);
             return new FloatFlowMass(f, unit);
         }
         catch (Exception exception)
         {
             throw new IllegalArgumentException(
                     "Error parsing FloatFlowMass from " + text + " using Locale " + Locale.getDefault(Locale.Category.FORMAT),
                     exception);
         }
     }
 
     /**
      * Returns a FloatFlowMass based on a value and the textual representation of the unit, which can be localized.
      * @param value the value to use
      * @param unitString the textual representation of the unit
      * @return the Scalar representation of the value in its unit
      * @throws IllegalArgumentException when the unit cannot be parsed or is incorrect
      * @throws NullPointerException when the unitString argument is null
      */
     public static FloatFlowMass of(final float value, final String unitString)
     {
         Throw.whenNull(unitString, "Error parsing FloatFlowMass: unitString is null");
         Throw.when(unitString.length() == 0, IllegalArgumentException.class, "Error parsing FloatFlowMass: empty unitString");
         FlowMassUnit unit = FlowMassUnit.BASE.getUnitByAbbreviation(unitString);
         Throw.when(unit == null, IllegalArgumentException.class, "Error parsing FloatFlowMass with unit %s", unitString);
         return new FloatFlowMass(value, unit);
     }
 
     /**
      * Calculate the division of FloatFlowMass and FloatFlowMass, which results in a FloatDimensionless scalar.
      * @param v scalar
      * @return scalar as a division of FloatFlowMass and FloatFlowMass
      */
     public final FloatDimensionless divide(final FloatFlowMass v)
     {
         return new FloatDimensionless(this.si / v.si, DimensionlessUnit.SI);
     }
 
     /**
      * Calculate the multiplication of FloatFlowMass and FloatDuration, which results in a FloatMass scalar.
      * @param v scalar
      * @return scalar as a multiplication of FloatFlowMass and FloatDuration
      */
     public final FloatMass times(final FloatDuration v)
     {
         return new FloatMass(this.si * v.si, MassUnit.SI);
     }
 
     /**
      * Calculate the division of FloatFlowMass and FloatFrequency, which results in a FloatMass scalar.
      * @param v scalar
      * @return scalar as a division of FloatFlowMass and FloatFrequency
      */
     public final FloatMass divide(final FloatFrequency v)
     {
         return new FloatMass(this.si / v.si, MassUnit.SI);
     }
 
     /**
      * Calculate the division of FloatFlowMass and FloatMass, which results in a FloatFrequency scalar.
      * @param v scalar
      * @return scalar as a division of FloatFlowMass and FloatMass
      */
     public final FloatFrequency divide(final FloatMass v)
     {
         return new FloatFrequency(this.si / v.si, FrequencyUnit.SI);
     }
 
     /**
      * Calculate the multiplication of FloatFlowMass and FloatSpeed, which results in a FloatForce scalar.
      * @param v scalar
      * @return scalar as a multiplication of FloatFlowMass and FloatSpeed
      */
     public final FloatForce times(final FloatSpeed v)
     {
         return new FloatForce(this.si * v.si, ForceUnit.SI);
     }
 
     /**
      * Calculate the division of FloatFlowMass and FloatFlowVolume, which results in a FloatDensity scalar.
      * @param v scalar
      * @return scalar as a division of FloatFlowMass and FloatFlowVolume
      */
     public final FloatDensity divide(final FloatFlowVolume v)
     {
         return new FloatDensity(this.si / v.si, DensityUnit.SI);
     }
 
     /**
      * Calculate the division of FloatFlowMass and FloatDensity, which results in a FloatFlowVolume scalar.
      * @param v scalar
      * @return scalar as a division of FloatFlowMass and FloatDensity
      */
     public final FloatFlowVolume divide(final FloatDensity v)
     {
         return new FloatFlowVolume(this.si / v.si, FlowVolumeUnit.SI);
     }
 
     /**
      * Calculate the multiplication of FloatFlowMass and FloatLength, which results in a FloatMomentum scalar.
      * @param v scalar
      * @return scalar as a multiplication of FloatFlowMass and FloatLength
      */
     public final FloatMomentum times(final FloatLength v)
     {
         return new FloatMomentum(this.si * v.si, MomentumUnit.SI);
     }
 
     @Override
     public FloatSIScalar reciprocal()
     {
         return FloatSIScalar.divide(FloatDimensionless.ONE, this);
     }
 
     /**
      * Multiply two scalars that result in a scalar of type FloatFlowMass.
      * @param scalar1 the first scalar
      * @param scalar2 the second scalar
      * @return the multiplication of both scalars as an instance of FloatFlowMass
      */
     public static FloatFlowMass multiply(final FloatScalarRel<?, ?> scalar1, final FloatScalarRel<?, ?> scalar2)
     {
         Throw.whenNull(scalar1, "scalar1 cannot be null");
         Throw.whenNull(scalar2, "scalar2 cannot be null");
         Throw.when(!scalar1.getDisplayUnit().getQuantity().getSiDimensions()
                 .plus(scalar2.getDisplayUnit().getQuantity().getSiDimensions()).equals(FlowMassUnit.BASE.getSiDimensions()),
                 IllegalArgumentException.class, "Multiplying %s by %s does not result in instance of type FloatFlowMass",
                 scalar1.toDisplayString(), scalar2.toDisplayString());
         return new FloatFlowMass(scalar1.si * scalar2.si, FlowMassUnit.SI);
     }
 
     /**
      * Divide two scalars that result in a scalar of type FloatFlowMass.
      * @param scalar1 the first scalar
      * @param scalar2 the second scalar
      * @return the division of scalar1 by scalar2 as an instance of FloatFlowMass
      */
     public static FloatFlowMass divide(final FloatScalarRel<?, ?> scalar1, final FloatScalarRel<?, ?> scalar2)
     {
         Throw.whenNull(scalar1, "scalar1 cannot be null");
         Throw.whenNull(scalar2, "scalar2 cannot be null");
         Throw.when(!scalar1.getDisplayUnit().getQuantity().getSiDimensions()
                 .minus(scalar2.getDisplayUnit().getQuantity().getSiDimensions()).equals(FlowMassUnit.BASE.getSiDimensions()),
                 IllegalArgumentException.class, "Dividing %s by %s does not result in an instance of type FloatFlowMass",
                 scalar1.toDisplayString(), scalar2.toDisplayString());
         return new FloatFlowMass(scalar1.si / scalar2.si, FlowMassUnit.SI);
     }
 
 }