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A multidimensional, type-agnostic image processing library.
/*
* #%L
* ImgLib2: a general-purpose, multidimensional image processing library.
* %%
* Copyright (C) 2009 - 2018 Tobias Pietzsch, Stephan Preibisch, Stephan Saalfeld,
* John Bogovic, Albert Cardona, Barry DeZonia, Christian Dietz, Jan Funke,
* Aivar Grislis, Jonathan Hale, Grant Harris, Stefan Helfrich, Mark Hiner,
* Martin Horn, Steffen Jaensch, Lee Kamentsky, Larry Lindsey, Melissa Linkert,
* Mark Longair, Brian Northan, Nick Perry, Curtis Rueden, Johannes Schindelin,
* Jean-Yves Tinevez and Michael Zinsmaier.
* %%
* 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.
*
* 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 HOLDERS 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.
* #L%
*/
package net.imglib2.img.planar;
import net.imglib2.Cursor;
import net.imglib2.FlatIterationOrder;
import net.imglib2.Interval;
import net.imglib2.img.AbstractNativeImg;
import net.imglib2.img.NativeImg;
import net.imglib2.img.basictypeaccess.PlanarAccess;
import net.imglib2.img.basictypeaccess.array.ArrayDataAccess;
import net.imglib2.type.NativeType;
import net.imglib2.util.Fraction;
import net.imglib2.util.Intervals;
import net.imglib2.view.iteration.SubIntervalIterable;
import java.util.ArrayList;
import java.util.List;
/**
* A {@link NativeImg} that stores data in an list of primitive arrays, one per
* image plane.
*
* The {@link PlanarImg} provides access to the underlying data arrays via the
* {@link #getPlane(int)} method.
*
*
* @author Jan Funke
* @author Stephan Preibisch
* @author Stephan Saalfeld
* @author Johannes Schindelin
* @author Tobias Pietzsch
*/
public class PlanarImg< T extends NativeType< T >, A extends ArrayDataAccess< A > > extends AbstractNativeImg< T, A > implements PlanarAccess< A >, SubIntervalIterable< T >
{
final protected int numSlices;
/*
* duplicate of long[] dimension as an int array.
*/
final protected int[] dimensions;
final protected int[] sliceSteps;
final protected List< A > mirror;
public PlanarImg( final List< A > slices, final long[] dim, final Fraction entitiesPerPixel )
{
super( dim, entitiesPerPixel );
this.dimensions = longToIntArray( dim );
this.sliceSteps = computeSliceSteps( dim );
this.numSlices = numberOfSlices( dim );
if(slices.size() != numSlices)
throw new IllegalArgumentException();
this.mirror = slices;
}
/** @deprecated Use {@link #PlanarImg(List, long[], Fraction)} instead. */
@Deprecated
public PlanarImg( final long[] dim, final Fraction entitiesPerPixel )
{
this( emptySlices( dim ), dim, entitiesPerPixel );
}
PlanarImg( final A creator, final long[] dim, final Fraction entitiesPerPixel )
{
this( createSlices( creator, dim, entitiesPerPixel ), dim, entitiesPerPixel );
}
/**
* This interface is implemented by all samplers on the {@link PlanarImg}.
* It allows the container to ask for the slice the sampler is currently in.
*/
public interface PlanarContainerSampler
{
/**
* @return the index of the slice the sampler is currently accessing.
*/
public int getCurrentSliceIndex();
}
@Override
public A update( final Object c )
{
final int i = ( ( PlanarContainerSampler ) c ).getCurrentSliceIndex();
return mirror.get( i < 0 ? 0 : ( i >= numSlices ? numSlices - 1 : i ) );
}
/**
* @return total number of image planes
*/
public int numSlices()
{
return numSlices;
}
/**
* For a given ≥2d location, estimate the pixel index in the stack slice.
*
* @param l
* @return
*
* TODO: remove this method? (it doesn't seem to be used anywhere)
*/
public final int getIndex( final int[] l )
{
if ( n > 1 )
return l[ 1 ] * dimensions[ 0 ] + l[ 0 ];
return l[ 0 ];
}
/**
* Compute a global position from the index of a slice and an index within
* that slice.
*
* @param sliceIndex
* index of slice
* @param indexInSlice
* index of element within slice
* @param position
* receives global position of element
*
* TODO: move this method to AbstractPlanarCursor? (that seems to
* be the only place where it is needed)
*/
public void indexToGlobalPosition( int sliceIndex, final int indexInSlice, final int[] position )
{
if ( n > 1 )
{
position[ 1 ] = indexInSlice / dimensions[ 0 ];
position[ 0 ] = indexInSlice - position[ 1 ] * dimensions[ 0 ];
if ( n > 2 )
{
final int maxDim = n - 1;
for ( int d = 2; d < maxDim; ++d )
{
final int j = sliceIndex / dimensions[ d ];
position[ d ] = sliceIndex - j * dimensions[ d ];
sliceIndex = j;
}
position[ maxDim ] = sliceIndex;
}
}
else
{
position[ 0 ] = indexInSlice;
}
}
/**
* Compute a global position from the index of a slice and an index within
* that slice.
*
* @param sliceIndex
* index of slice
* @param indexInSlice
* index of element within slice
* @param dim
* which dimension of the position we are interested in
* @return dimension dim of global position
*
* TODO: move this method to AbstractPlanarCursor? (that seems to be
* the only place where it is needed)
*/
public int indexToGlobalPosition( final int sliceIndex, final int indexInSlice, final int dim )
{
if ( dim == 0 )
return indexInSlice % dimensions[ 0 ];
else if ( dim == 1 )
return indexInSlice / dimensions[ 0 ];
else if ( dim < n )
return ( sliceIndex / sliceSteps[ dim ] ) % dimensions[ dim ];
else
return 0;
}
@Override
public PlanarCursor< T > cursor()
{
if ( n == 1 )
return new PlanarCursor1D< T >( this );
else if ( n == 2 )
return new PlanarCursor2D< T >( this );
else
return new PlanarCursor< T >( this );
}
@Override
public PlanarLocalizingCursor< T > localizingCursor()
{
if ( n == 1 )
return new PlanarLocalizingCursor1D< T >( this );
else if ( n == 2 )
return new PlanarLocalizingCursor2D< T >( this );
else
return new PlanarLocalizingCursor< T >( this );
}
@Override
public PlanarRandomAccess< T > randomAccess()
{
if ( n == 1 )
return new PlanarRandomAccess1D< T >( this );
return new PlanarRandomAccess< T >( this );
}
@Override
public FlatIterationOrder iterationOrder()
{
return new FlatIterationOrder( this );
}
@Override
public A getPlane( final int no )
{
return mirror.get( no );
}
@Override
public void setPlane( final int no, final A plane )
{
mirror.set( no, plane );
}
@Override
public PlanarImgFactory< T > factory()
{
return new PlanarImgFactory<>( linkedType );
}
@Override
public PlanarImg< T, ? > copy()
{
final PlanarImg< T, ? > copy = factory().create( dimension );
final PlanarCursor< T > cursor1 = this.cursor();
final PlanarCursor< T > cursor2 = copy.cursor();
while ( cursor1.hasNext() )
cursor2.next().set( cursor1.next() );
return copy;
}
/**
* {@inheritDoc}
*/
@Override
public boolean supportsOptimizedCursor( final Interval interval )
{
// we want to optimize exactly one plane
return Intervals.contains( this, interval ) && correspondsToPlane( interval );
}
/**
* {@inheritDoc}
*/
@Override
public Object subIntervalIterationOrder( final Interval interval )
{
return new FlatIterationOrder( interval );
}
/**
* {@inheritDoc}
*/
@Override
public Cursor< T > cursor( final Interval interval )
{
assert ( supportsOptimizedCursor( interval ) );
return new PlanarPlaneSubsetCursor< T >( this, interval );
}
private boolean correspondsToPlane( final Interval interval )
{
// check if interval describes one plane
if ( interval.dimension( 0 ) != dimension[ 0 ] )
return false;
if ( dimension.length == 1 )
return true;
if ( interval.dimension( 1 ) != dimension[ 1 ] )
return false;
for ( int d = 2; d < interval.numDimensions(); ++d )
{
if ( interval.dimension( d ) != 1 )
return false;
}
return true;
}
/**
* {@inheritDoc}
*/
@Override
public Cursor< T > localizingCursor( final Interval interval )
{
assert ( supportsOptimizedCursor( interval ) );
return new PlanarPlaneSubsetLocalizingCursor< T >( this, interval );
}
/**
* How many slices has a PlanarImg with the given dimensions?
*/
public static int numberOfSlices( long[] dimensions )
{
int s = 1;
for ( int d = 2; d < dimensions.length; ++d )
s *= dimensions[ d ];
return s;
}
// -- Helper methods --
private static int[] longToIntArray( long[] dim )
{
int[] dimensions = new int[ dim.length ];
for ( int d = 0; d < dim.length; ++d )
dimensions[ d ] = ( int ) dim[ d ];
return dimensions;
}
private static int[] computeSliceSteps( long[] dimensions )
{
final int n = dimensions.length;
if ( n <= 2 )
return null;
int[] sliceSteps = new int[ n ];
sliceSteps[ 2 ] = 1;
for ( int i = 3; i < n; ++i )
sliceSteps[ i ] = ( int ) dimensions[ i - 1 ] * sliceSteps[ i - 1 ];
return sliceSteps;
}
private static < A > List< A > emptySlices( long[] dim )
{
int numSlices = numberOfSlices( dim );
List< A > mirror = new ArrayList<>( numSlices );
for ( int i = 0; i < numSlices; ++i )
mirror.add( null );
return mirror;
}
private static < A extends ArrayDataAccess< A > > List< A > createSlices( A creator, long[] dim, Fraction entitiesPerPixel )
{
int numSlices = numberOfSlices( dim );
List< A > mirror = new ArrayList<>( numSlices );
final int pixelsPerPlane = (int) (( ( dim.length > 1 ) ? dim[ 1 ] : 1 ) * dim[ 0 ]);
final int numEntitiesPerSlice = ( int ) entitiesPerPixel.mulCeil( pixelsPerPlane );
for ( int i = 0; i < numSlices; ++i )
mirror.add( creator.createArray( numEntitiesPerSlice ) );
return mirror;
}
}