source: branches/HeuristicLab.Problems.GaussianProcessTuning/ILNumerics.2.14.4735.573/Functions/builtin/new.cs @ 9407

///
///    This file is part of ILNumerics Community Edition.
///
///    ILNumerics Community Edition - high performance computing for applications.
///    Copyright (C) 2006 - 2012 Haymo Kutschbach, http://ilnumerics.net
///
///    ILNumerics Community Edition is free software: you can redistribute it and/or modify
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///    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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///    along with ILNumerics Community Edition. See the file License.txt in the root
///    of your distribution package. If not, see <http://www.gnu.org/licenses/>.
///
///    In addition this software uses the following components and/or licenses: 
///
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///    The Open Toolkit Library License
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///    Copyright (c) 2006 - 2009 the Open Toolkit library.
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///    of this software and associated documentation files (the "Software"), to deal
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using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;

namespace ILNumerics {
    public partial class ILMath {
        /// <summary>
        /// Request System.Array <typeparamref name="T"/>[] from ILNumerics Memory Pool
        /// </summary>
        /// <typeparam name="T">the element type</typeparam>
        /// <param name="length"><b>minimal</b> length of the array returned</param>
        /// <returns>A system array of element type <typeparamref name="T"/> and minimal length <paramref name="length"/>.</returns>
        /// <remarks>
        /// <para>This function fetches a System.Array from the collection of available arrays with matching properties which are currently held in the ILNumerics Memory Pool. 
        /// This simplifies usage scenarios where the user must handle System.Arrays in computational loops and still wants to profit from the ILNumerics memory management.</para>
        /// <para>The array returned is fetched from the collection of available arrays in the pool. If no matching array was found, a new array is requested from the managed heap.</para>
        /// <para>The user is reponsible to return the array to the pool once finished using it. The <see cref="ILNumerics.ILMath.free{T}"/> method should be used for returning an array.</para>
        /// <para>Keep in mind, the array returned may be <b>longer</b> as requested! Therefore, in order to reference its elements use the <paramref name="length"/> parameter rather than the System.Array.Length property.</para>
        /// <example>A system array is needed inside a computational loop. The loop calls a native function repeatedly which requests a working array. The System.Array is requested from the pool and returned to the pool after usage.
        /// <code>
        ///[System.Runtime.InteropServices.DllImport("myDLL")]
        ///private static extern void MyDllFunc(double[] a, int lenA, double[] b, double[] work, int lenWork);
        ///
        ///public static ILRetArray<double> MyFunc(ILInArray<double> A) {
        ///    using (ILScope.Enter(A)) {
        ///        // myDllFunc needs storage for the result
        ///        ILArray<double> ret = zeros(A.Size);
        ///        ILArray<double> tmpRow = zeros(1, A.S[1]);
        ///
        ///        // myDllFunc needs a working storage:
        ///        double[] work = New<double>(A.S[1]);
        ///        // for all rows of A use the same working array
        ///        for (int i = 0; i < A.S[0]; i++) {
        ///            using (ILScope.Enter()) {
        ///                ILArray<double> ARow = A[i, full];
        ///                MyDllFunc(ARow.GetArrayForRead(), A.Length, tmpRow.GetArrayForWrite(), work, A.Length);
        ///                ret[i, full] = tmpRow;
        ///            }
        ///        }
        ///        // return the System.Array to the pool 
        ///        free(work);
        ///        return ret;
        ///    }
        ///}
        /// </code>
        /// However, in most situations, the handling of system.arrays directly can be circumvented. The same goal as in the example could be archieved as follows: 
        /// <code>        
        /// public static ILRetArray<double> MyFunc(ILInArray<double> A) {
        ///using (ILScope.Enter(A)) {
        ///    // myDllFunc needs storage for the result
        ///    ILArray<double> ret = zeros(A.Size);
        ///    ILArray<double> tmpRow = zeros(1, A.S[1]);
        ///    // myDllFunc needs a working storage. We us a regular ILNumerics array 
        ///    // which we dont have to free afterwards. 
        ///    ILArray<double> work = zeros(tmpRow.S); 
        ///
        ///    // for all rows of A use the same working array
        ///    for (int i = 0; i < A.S[0]; i++) {
        ///        using (ILScope.Enter()) {
        ///            ILArray<double> ARow = A[i, full];
        ///            MyDllFunc(ARow.GetArrayForRead(), A.Length, tmpRow.GetArrayForWrite(), work.GetArrayForWrite(), A.Length);
        ///            ret[i, full] = tmpRow;
        ///        }
        ///    }
        ///    // returning the working storage is not needed here...
        ///
        ///    return ret;
        ///}
        ///}</code>
        /// Both examples archieve a 100% memory efficiency by completely reusing the memory needed within the function. 
        /// </example>
        /// </remarks>
        public static T[] New<T>(int length) {
            return ILMemoryPool.Pool.New<T>(length); 
        }
    }
}