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/*
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 * ImgLib2: a general-purpose, multidimensional image processing library.
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 * John Bogovic, Albert Cardona, Barry DeZonia, Christian Dietz, Jan Funke,
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 * Martin Horn, Steffen Jaensch, Lee Kamentsky, Larry Lindsey, Melissa Linkert,
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 * Jean-Yves Tinevez and Michael Zinsmaier.
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package net.imglib2.view;

import java.util.LinkedList;
import java.util.ListIterator;

import net.imglib2.Interval;
import net.imglib2.RandomAccess;
import net.imglib2.RandomAccessible;
import net.imglib2.RandomAccessibleInterval;
import net.imglib2.img.WrappedImg;
import net.imglib2.transform.Transform;
import net.imglib2.transform.integer.BoundingBox;
import net.imglib2.transform.integer.BoundingBoxTransform;
import net.imglib2.transform.integer.Mixed;
import net.imglib2.transform.integer.MixedTransform;
import net.imglib2.transform.integer.SlicingTransform;
import net.imglib2.transform.integer.TranslationTransform;
import net.imglib2.util.Intervals;

/**
 * The "brain" of the Views framework. Simplifies View cascades to provide the
 * most efficient accessor for a specified Interval.
 * 
 * @see #getEfficientRandomAccessible(Interval, RandomAccessible)
 * 
 * @author Tobias Pietzsch
 */
public class TransformBuilder< T >
{
	/**
	 * Get a RandomAccessible which provides RandomAccess to the specified
	 * {@code interval} of {@code randomAccessible}.
	 * 
	 * 

* Create a new TransformBuilder that traverses the view hierarchy starting * from {@code randomAccessible}. {@link #build()} an efficient * RandomAccessible by joining and simplifying the collected * transformations. *

* * @param interval * The interval in which access is needed. * @param randomAccessible */ public static < S > RandomAccessible< S > getEfficientRandomAccessible( final Interval interval, final RandomAccessible< S > randomAccessible ) { return new TransformBuilder< S >( interval, randomAccessible ).build(); } /** * Provides the untransformed random access. */ protected RandomAccessible< T > source; /** * Interval transformed to the currently visited view. null means that the * interval is infinite. */ protected BoundingBox boundingBox; /** * List of transforms that have to be applied when wrapping the * {@link #source} RandomAccess to obtain a RandomAccess in the target * coordinate system. */ protected LinkedList< Transform > transforms; /** * Create a new TransformBuilder. Starting from {@code randomAccessible}, go * down the view hierarchy to the RandomAccessible that will provide the * source RandomAccess into the specified {@code interval}. While traversing * the view hierarchy transforms are collected into the {@link #transforms} * list. These transforms have to be applied when wrapping the source * RandomAccess to obtain a RandomAccess in the coordinate system of * {@code randomAccessible}. * * @param interval * The interval in which access is needed. This is converted to a * bounding box which is propagated through the transforms down * the view hierarchy. * @param randomAccessible */ protected TransformBuilder( final Interval interval, final RandomAccessible< T > randomAccessible ) { transforms = new LinkedList< Transform >(); boundingBox = ( interval == null ) ? null : new BoundingBox( interval ); // System.out.println( randomAccessible ); visit( randomAccessible ); simplifyTransforms(); } /** * Prepend a transform to the {@link #transforms} list. Also apply the * transform to {@link #boundingBox}, which will be used to specify the * interval for the RandomAccess on the final source (at the end of the view * chain). This is called while traversing the view hierarchy. * * @param t * the transform to add. */ protected void prependTransform( final Transform t ) { if ( BoundingBoxTransform.class.isInstance( t ) && ( boundingBox != null ) ) boundingBox = ( ( BoundingBoxTransform ) t ).transform( boundingBox ); else boundingBox = null; transforms.addFirst( t ); } /** * Visit a RandomAccessible (while traversing the view hierarchy). The * {@code randomAccessible} is handled by * {@link #visitTransformed(TransformedRandomAccessible)} or * {@link #visitExtended(ExtendedRandomAccessibleInterval)} when it has the * appropriate type. Otherwise, the traversal stops and * {@code randomAccessible} is set as the {@link #source}. * * @param randomAccessible */ @SuppressWarnings( "unchecked" ) protected void visit( final RandomAccessible< T > randomAccessible ) { if ( TransformedRandomAccessible.class.isInstance( randomAccessible ) ) { visitTransformed( ( TransformedRandomAccessible< T > ) randomAccessible ); } else if ( ExtendedRandomAccessibleInterval.class.isInstance( randomAccessible ) ) { visitExtended( ( ExtendedRandomAccessibleInterval< T, ? > ) randomAccessible ); } else if ( IntervalView.class.isInstance( randomAccessible ) ) { visit( ( ( IntervalView< T > ) randomAccessible ).getSource() ); } else if ( WrappedImg.class.isInstance( randomAccessible ) ) { visit( ( ( WrappedImg< T > ) randomAccessible ).getImg() ); } else { source = randomAccessible; } } /** * Visit a TransformedRandomAccessible (while traversing the view * hierarchy). Append the view's transform to the list and * {@link #visit(RandomAccessible)} the view's source. * * @param randomAccessible */ protected void visitTransformed( final TransformedRandomAccessible< T > randomAccessible ) { prependTransform( randomAccessible.getTransformToSource() ); visit( randomAccessible.getSource() ); } /** * Visit a ExtendedRandomAccessibleInterval (while traversing the view * hierarchy). If the no out-of-bounds extension is needed for the current * bounding box, {@link #visit(RandomAccessible)} the view's source. * Otherwise, the traversal stops and {@code randomAccessible} is set as the * {@link #source}. * * @param randomAccessible */ protected void visitExtended( final ExtendedRandomAccessibleInterval< T, ? > randomAccessible ) { final RandomAccessibleInterval< T > sourceInterval = randomAccessible.getSource(); if ( ( boundingBox != null ) && Intervals.contains( sourceInterval, boundingBox.getInterval() ) ) visit( sourceInterval ); else source = randomAccessible; } public static boolean isIdentity( final Mixed t ) { final int n = t.numSourceDimensions(); final int m = t.numTargetDimensions(); if ( n != m ) return false; for ( int d = 0; d < m; ++d ) { if ( t.getTranslation( d ) != 0 ) return false; if ( t.getComponentZero( d ) ) return false; if ( t.getComponentInversion( d ) ) return false; if ( t.getComponentMapping( d ) != d ) return false; } return true; } public static boolean isTranslation( final Mixed t ) { final int n = t.numSourceDimensions(); final int m = t.numTargetDimensions(); if ( n != m ) return false; for ( int d = 0; d < m; ++d ) { if ( t.getComponentZero( d ) ) return false; if ( t.getComponentInversion( d ) ) return false; if ( t.getComponentMapping( d ) != d ) return false; } return true; } public static boolean isComponentMapping( final Mixed t ) { final int m = t.numTargetDimensions(); for ( int d = 0; d < m; ++d ) { if ( t.getTranslation( d ) != 0 ) return false; if ( t.getComponentZero( d ) ) return false; if ( t.getComponentInversion( d ) ) return false; } return true; } public static boolean isSlicing( final Mixed t ) { final int n = t.numSourceDimensions(); final int m = t.numTargetDimensions(); if ( n > m ) return false; for ( int d = 0; d < m; ++d ) { if ( t.getTranslation( d ) != 0 && ( !t.getComponentZero( d ) ) ) return false; if ( t.getComponentInversion( d ) ) return false; } return true; } /** * Simplify the {@link #transforms} list. First, concatenate neighboring * transforms if possible. Then, for every {@link Mixed} transform: *
    *
  • remove it if it is the identity transforms. *
  • replace it by a {@link TranslationTransform} if it is a pure * translation. *
  • replace it by a {@link SlicingTransform} if it is a pure slicing. *
*/ protected void simplifyTransforms() { net.imglib2.concatenate.ConcatenateUtils.join( transforms ); for ( final ListIterator< Transform > i = transforms.listIterator(); i.hasNext(); ) { final Transform t = i.next(); if ( Mixed.class.isInstance( t ) ) { final Mixed mixed = ( Mixed ) t; if ( isIdentity( mixed ) ) { // found identity // remove from transforms list i.remove(); } else if ( isTranslation( mixed ) ) { // found pure translation // replace by a TranslationTransform final long[] translation = new long[ mixed.numTargetDimensions() ]; mixed.getTranslation( translation ); i.set( new TranslationTransform( translation ) ); } // else if ( isComponentMapping( mixed ) ) // { // // found pure component mapping // // replace by a ComponentMappingTransform // final int[] component = new int[ mixed.numTargetDimensions() ]; // mixed.getComponentMapping( component ); // i.set( new ComponentMappingTransform( component ) ); // } else if ( isSlicing( mixed ) ) { // found pure slicing // replace by a SlicingTransform final int m = mixed.numTargetDimensions(); final long[] translation = new long[ m ]; final boolean[] zero = new boolean[ m ]; final int[] component = new int[ m ]; mixed.getTranslation( translation ); mixed.getComponentZero( zero ); mixed.getComponentMapping( component ); final SlicingTransform sl = new SlicingTransform( mixed.numSourceDimensions(), m ); sl.setTranslation( translation ); sl.setComponentZero( zero ); sl.setComponentMapping( component ); i.set( sl ); } } } } /** * Create a sequence of wrapped RandomAccessibles from the * {@link #transforms} list. * * @return RandomAccessible on the interval specified in the constructor. */ protected RandomAccessible< T > build() { RandomAccessible< T > result = source; for ( final ListIterator< Transform > i = transforms.listIterator(); i.hasNext(); ) { final Transform t = i.next(); if ( MixedTransform.class.isInstance( t ) ) result = wrapMixedTransform( result, ( MixedTransform ) t ); else if ( TranslationTransform.class.isInstance( t ) ) result = wrapTranslationTransform( result, ( TranslationTransform ) t ); else if ( SlicingTransform.class.isInstance( t ) ) result = wrapSlicingTransform( result, ( SlicingTransform ) t ); else result = wrapGenericTransform( result, t ); } return result; } protected RandomAccessible< T > wrapGenericTransform( final RandomAccessible< T > s, final Transform t ) { return new RandomAccessible< T >() { @Override public int numDimensions() { return t.numSourceDimensions(); } @Override public RandomAccess< T > randomAccess() { return new TransformRandomAccess< T >( s.randomAccess(), t ); } @Override public RandomAccess< T > randomAccess( final Interval interval ) { return new TransformRandomAccess< T >( s.randomAccess(), t ); } }; } protected RandomAccessible< T > wrapMixedTransform( final RandomAccessible< T > s, final MixedTransform t ) { final boolean full = t.hasFullSourceMapping(); return new RandomAccessible< T >() { @Override public int numDimensions() { return t.numSourceDimensions(); } @Override public RandomAccess< T > randomAccess() { if ( full ) return new FullSourceMapMixedRandomAccess< T >( s.randomAccess(), t ); return new MixedRandomAccess< T >( s.randomAccess(), t ); } @Override public RandomAccess< T > randomAccess( final Interval interval ) { if ( full ) return new FullSourceMapMixedRandomAccess< T >( s.randomAccess(), t ); return new MixedRandomAccess< T >( s.randomAccess(), t ); } }; } protected RandomAccessible< T > wrapTranslationTransform( final RandomAccessible< T > s, final TranslationTransform t ) { return new RandomAccessible< T >() { @Override public int numDimensions() { return t.numSourceDimensions(); } @Override public TranslationRandomAccess< T > randomAccess() { return new TranslationRandomAccess< T >( s.randomAccess(), t ); } @Override public TranslationRandomAccess< T > randomAccess( final Interval interval ) { return new TranslationRandomAccess< T >( s.randomAccess(), t ); } }; } protected RandomAccessible< T > wrapSlicingTransform( final RandomAccessible< T > s, final SlicingTransform t ) { final boolean full = t.hasFullSourceMapping(); return new RandomAccessible< T >() { @Override public int numDimensions() { return t.numSourceDimensions(); } @Override public RandomAccess< T > randomAccess() { if ( full ) return new FullSourceMapSlicingRandomAccess< T >( s.randomAccess(), t ); return new SlicingRandomAccess< T >( s.randomAccess(), t ); } @Override public RandomAccess< T > randomAccess( final Interval interval ) { if ( full ) return new FullSourceMapSlicingRandomAccess< T >( s.randomAccess(), t ); return new SlicingRandomAccess< T >( s.randomAccess(), t ); } }; } }




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