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[jalview.git] / src / jalview / analysis / PCA.java

/*\r
 * Jalview - A Sequence Alignment Editor and Viewer\r
 * Copyright (C) 2007 AM Waterhouse, J Procter, G Barton, M Clamp, S Searle\r
 *\r
 * This program is free software; you can redistribute it and/or\r
 * modify it under the terms of the GNU General Public License\r
 * as published by the Free Software Foundation; either version 2\r
 * of the License, or (at your option) any later version.\r
 *\r
 * This program is distributed in the hope that it will be useful,\r
 * but WITHOUT ANY WARRANTY; without even the implied warranty of\r
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the\r
 * GNU General Public License for more details.\r
 *\r
 * You should have received a copy of the GNU General Public License\r
 * along with this program; if not, write to the Free Software\r
 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301, USA\r
 */\r
package jalview.analysis;\r
\r
import java.io.*;\r
\r
import jalview.datamodel.*;\r
import jalview.math.*;\r
\r
/**\r
 * Performs Principal Component Analysis on given sequences\r
 *\r
 * @author $author$\r
 * @version $Revision$\r
 */\r
public class PCA\r
    implements Runnable\r
{\r
  Matrix m;\r
  Matrix symm;\r
  Matrix m2;\r
  double[] eigenvalue;\r
  Matrix eigenvector;\r
  StringBuffer details = new StringBuffer();\r
\r
  /**\r
   * Creates a new PCA object.\r
   *\r
   * @param s Set of sequences to perform PCA on\r
   */\r
  public PCA(String[] s)\r
  {\r
\r
    BinarySequence[] bs = new BinarySequence[s.length];\r
    int ii = 0;\r
\r
    while ( (ii < s.length) && (s[ii] != null))\r
    {\r
      bs[ii] = new BinarySequence(s[ii]);\r
      bs[ii].encode();\r
      ii++;\r
    }\r
\r
    BinarySequence[] bs2 = new BinarySequence[s.length];\r
    ii = 0;\r
\r
    while ( (ii < s.length) && (s[ii] != null))\r
    {\r
      bs2[ii] = new BinarySequence(s[ii]);\r
      bs2[ii].blosumEncode();\r
      ii++;\r
    }\r
\r
    //System.out.println("Created binary encoding");\r
    //printMemory(rt);\r
    int count = 0;\r
\r
    while ( (count < bs.length) && (bs[count] != null))\r
    {\r
      count++;\r
    }\r
\r
    double[][] seqmat = new double[count][bs[0].getDBinary().length];\r
    double[][] seqmat2 = new double[count][bs2[0].getDBinary().length];\r
    int i = 0;\r
\r
    while (i < count)\r
    {\r
      seqmat[i] = bs[i].getDBinary();\r
      seqmat2[i] = bs2[i].getDBinary();\r
      i++;\r
    }\r
\r
    //System.out.println("Created array");\r
    //printMemory(rt);\r
    //    System.out.println(" --- Original matrix ---- ");\r
    m = new Matrix(seqmat, count, bs[0].getDBinary().length);\r
    m2 = new Matrix(seqmat2, count, bs2[0].getDBinary().length);\r
\r
  }\r
\r
  /**\r
   * Returns the matrix used in PCA calculation\r
   *\r
   * @return java.math.Matrix object\r
   */\r
\r
  public Matrix getM()\r
  {\r
    return m;\r
  }\r
\r
  /**\r
   * Returns Eigenvalue\r
   *\r
   * @param i Index of diagonal within matrix\r
   *\r
   * @return Returns value of diagonal from matrix\r
   */\r
  public double getEigenvalue(int i)\r
  {\r
    return eigenvector.d[i];\r
  }\r
\r
  /**\r
   * DOCUMENT ME!\r
   *\r
   * @param l DOCUMENT ME!\r
   * @param n DOCUMENT ME!\r
   * @param mm DOCUMENT ME!\r
   * @param factor DOCUMENT ME!\r
   *\r
   * @return DOCUMENT ME!\r
   */\r
  public float[][] getComponents(int l, int n, int mm, float factor)\r
  {\r
    float[][] out = new float[m.rows][3];\r
\r
    for (int i = 0; i < m.rows; i++)\r
    {\r
      out[i][0] = (float) component(i, l) * factor;\r
      out[i][1] = (float) component(i, n) * factor;\r
      out[i][2] = (float) component(i, mm) * factor;\r
    }\r
\r
    return out;\r
  }\r
\r
  /**\r
   * DOCUMENT ME!\r
   *\r
   * @param n DOCUMENT ME!\r
   *\r
   * @return DOCUMENT ME!\r
   */\r
  public double[] component(int n)\r
  {\r
    // n = index of eigenvector\r
    double[] out = new double[m.rows];\r
\r
    for (int i = 0; i < m.rows; i++)\r
    {\r
      out[i] = component(i, n);\r
    }\r
\r
    return out;\r
  }\r
\r
  /**\r
   * DOCUMENT ME!\r
   *\r
   * @param row DOCUMENT ME!\r
   * @param n DOCUMENT ME!\r
   *\r
   * @return DOCUMENT ME!\r
   */\r
  double component(int row, int n)\r
  {\r
    double out = 0.0;\r
\r
    for (int i = 0; i < symm.cols; i++)\r
    {\r
      out += (symm.value[row][i] * eigenvector.value[i][n]);\r
    }\r
\r
    return out / eigenvector.d[n];\r
  }\r
\r
  public String getDetails()\r
  {\r
    return details.toString();\r
  }\r
\r
  /**\r
   * DOCUMENT ME!\r
   */\r
  public void run()\r
  {\r
    Matrix mt = m.transpose();\r
\r
    details.append(" --- OrigT * Orig ---- \n");\r
    eigenvector = mt.preMultiply(m2);\r
\r
    PrintStream ps = new PrintStream(System.out)\r
    {\r
      public void print(String x)\r
      {\r
        details.append(x);\r
      }\r
\r
      public void println()\r
      {\r
        details.append("\n");\r
      }\r
    };\r
\r
    eigenvector.print(ps);\r
\r
    symm = eigenvector.copy();\r
\r
    eigenvector.tred();\r
\r
    details.append(" ---Tridiag transform matrix ---\n");\r
    details.append(" --- D vector ---\n");\r
    eigenvector.printD(ps);\r
    ps.println();\r
    details.append("--- E vector ---\n");\r
    eigenvector.printE(ps);\r
    ps.println();\r
\r
    // Now produce the diagonalization matrix\r
    eigenvector.tqli();\r
\r
    details.append(" --- New diagonalization matrix ---\n");\r
    details.append(" --- Eigenvalues ---\n");\r
    eigenvector.printD(ps);\r
    ps.println();\r
    //  taps.println();\r
    //  taps.println("Transformed sequences = ");\r
    // Matrix trans =  m.preMultiply(eigenvector);\r
    //  trans.print(System.out);\r
  }\r
}\r