/*
- * Jalview - A Sequence Alignment Editor and Viewer (Version 2.8.2)
- * Copyright (C) 2014 The Jalview Authors
+ * Jalview - A Sequence Alignment Editor and Viewer ($$Version-Rel$$)
+ * Copyright (C) $$Year-Rel$$ The Jalview Authors
*
* This file is part of Jalview.
*
*/
package jalview.schemes;
+import jalview.analysis.scoremodels.FeatureScoreModel;
import jalview.analysis.scoremodels.PIDScoreModel;
import jalview.api.analysis.ScoreModelI;
import java.awt.Color;
import java.util.ArrayList;
import java.util.Enumeration;
+import java.util.HashMap;
import java.util.Hashtable;
import java.util.List;
import java.util.Map;
public class ResidueProperties
{
- public static Hashtable<String, ScoreModelI> scoreMatrices = new Hashtable();
+ public static Hashtable<String, ScoreModelI> scoreMatrices = new Hashtable<String, ScoreModelI>();
// Stores residue codes/names and colours and other things
public static final int[] aaIndex; // aaHash version 2.1.1 and below
public static final int[] purinepyrimidineIndex;
- public static final Hashtable aa3Hash = new Hashtable();
+ public static final Map<String, Integer> aa3Hash = new HashMap<String, Integer>();
- public static final Hashtable aa2Triplet = new Hashtable();
+ public static final Map<String, String> aa2Triplet = new HashMap<String, String>();
- public static final Hashtable nucleotideName = new Hashtable();
+ public static final Map<String, String> nucleotideName = new HashMap<String, String>();
+
+ // lookup from modified amino acid (e.g. MSE) to canonical form (e.g. MET)
+ public static final Map<String, String> modifications = new HashMap<String, String>();
static
{
aa2Triplet.put("v", "VAL");
}
- public static final String[] aa =
- { "A", "R", "N", "D", "C", "Q", "E", "G", "H", "I", "L", "K", "M", "F",
- "P", "S", "T", "W", "Y", "V", "B", "Z", "X", "_", "*", ".", " " };
+ public static final String[] aa = { "A", "R", "N", "D", "C", "Q", "E",
+ "G", "H", "I", "L", "K", "M", "F", "P", "S", "T", "W", "Y", "V", "B",
+ "Z", "X", "_", "*", ".", " " };
public static final Color midBlue = new Color(100, 100, 255);
scaleColours.addElement(Color.white);
}
- public static final Color[] taylor =
- { new Color(204, 255, 0), // A Greenish-yellowy-yellow
+ public static final Color[] taylor = { new Color(204, 255, 0), // A
+ // Greenish-yellowy-yellow
new Color(0, 0, 255), // R Blueish-bluey-blue
new Color(204, 0, 255), // N Blueish-reddy-blue
new Color(255, 0, 0), // D Reddish-reddy-red
Color.white // .
};
- public static final Color[] nucleotide =
- { new Color(100, 247, 63), // A
+ public static final Color[] nucleotide = { new Color(100, 247, 63), // A
new Color(255, 179, 64), // C
new Color(235, 65, 60), // G
new Color(60, 136, 238), // T
};
// Added for PurinePyrimidineColourScheme
- public static final Color[] purinepyrimidine =
- { new Color(255, 131, 250), // A, G, R purines purplish/orchid
+ public static final Color[] purinepyrimidine = {
+ new Color(255, 131, 250), // A, G, R purines purplish/orchid
new Color(64, 224, 208), // C,U, T, Y pyrimidines turquoise
Color.white, // all other nucleotides
Color.white // Gap
};
// Zappo
- public static final Color[] zappo =
- { Color.pink, // A
+ public static final Color[] zappo = { Color.pink, // A
midBlue, // R
Color.green, // N
Color.red, // D
};
// Dunno where I got these numbers from
- public static final double[] hyd2 =
- { 0.62, // A
+ public static final double[] hyd2 = { 0.62, // A
0.29, // R
-0.90, // N
-0.74, // D
0.0 // X
};
- public static final double[] helix =
- { 1.42, 0.98, 0.67, 1.01, 0.70, 1.11, 1.51, 0.57, 1.00, 1.08, 1.21, 1.16,
- 1.45, 1.13, 0.57, 0.77, 0.83, 1.08, 0.69, 1.06, 0.84, 1.31, 1.00, 0.0 };
+ public static final double[] helix = { 1.42, 0.98, 0.67, 1.01, 0.70,
+ 1.11, 1.51, 0.57, 1.00, 1.08, 1.21, 1.16, 1.45, 1.13, 0.57, 0.77,
+ 0.83, 1.08, 0.69, 1.06, 0.84, 1.31, 1.00, 0.0 };
public static final double helixmin = 0.57;
public static final double helixmax = 1.51;
- public static final double[] strand =
- { 0.83, 0.93, 0.89, 0.54, 1.19, 1.10, 0.37, 0.75, 0.87, 1.60, 1.30, 0.74,
- 1.05, 1.38, 0.55, 0.75, 1.19, 1.37, 1.47, 1.70, 0.72, 0.74, 1.0, 0.0 };
+ public static final double[] strand = { 0.83, 0.93, 0.89, 0.54, 1.19,
+ 1.10, 0.37, 0.75, 0.87, 1.60, 1.30, 0.74, 1.05, 1.38, 0.55, 0.75,
+ 1.19, 1.37, 1.47, 1.70, 0.72, 0.74, 1.0, 0.0 };
public static final double strandmin = 0.37;
public static final double strandmax = 1.7;
- public static final double[] turn =
- { 0.66, 0.95, 1.56, 1.46, 1.19, 0.98, 0.74, 1.56, 0.95, 0.47, 0.59, 1.01,
- 0.60, 0.60, 1.52, 1.43, 0.96, 0.96, 1.14, 0.50, 1.51, 0.86, 1.00, 0,
- 0 };
+ public static final double[] turn = { 0.66, 0.95, 1.56, 1.46, 1.19, 0.98,
+ 0.74, 1.56, 0.95, 0.47, 0.59, 1.01, 0.60, 0.60, 1.52, 1.43, 0.96,
+ 0.96, 1.14, 0.50, 1.51, 0.86, 1.00, 0, 0 };
public static final double turnmin = 0.47;
public static final double turnmax = 1.56;
- public static final double[] buried =
- { 1.7, 0.1, 0.4, 0.4, 4.6, 0.3, 0.3, 1.8, 0.8, 3.1, 2.4, 0.05, 1.9, 2.2,
- 0.6, 0.8, 0.7, 1.6, 0.5, 2.9, 0.4, 0.3, 1.358, 0.00 };
+ public static final double[] buried = { 1.7, 0.1, 0.4, 0.4, 4.6, 0.3,
+ 0.3, 1.8, 0.8, 3.1, 2.4, 0.05, 1.9, 2.2, 0.6, 0.8, 0.7, 1.6, 0.5,
+ 2.9, 0.4, 0.3, 1.358, 0.00 };
public static final double buriedmin = 0.05;
// This is hydropathy index
// Kyte, J., and Doolittle, R.F., J. Mol. Biol.
// 1157, 105-132, 1982
- public static final double[] hyd =
- { 1.8, -4.5, -3.5, -3.5, 2.5, -3.5, -3.5, -0.4, -3.2, 4.5, 3.8, -3.9,
- 1.9, 2.8, -1.6, -0.8, -0.7, -0.9, -1.3, 4.2, -3.5, -3.5, -0.49, 0.0 };
+ public static final double[] hyd = { 1.8, -4.5, -3.5, -3.5, 2.5, -3.5,
+ -3.5, -0.4, -3.2, 4.5, 3.8, -3.9, 1.9, 2.8, -1.6, -0.8, -0.7, -0.9,
+ -1.3, 4.2, -3.5, -3.5, -0.49, 0.0 };
public static final double hydmax = 4.5;
// public static final double hydmax = 1.38;
// public static final double hydmin = -2.53;
- private static final int[][] BLOSUM62 =
- {
+ private static final int[][] BLOSUM62 = {
{ 4, -1, -2, -2, 0, -1, -1, 0, -2, -1, -1, -1, -1, -2, -1, 1, 0, -3,
-2, 0, -2, -1, 0, -4 },
{ -1, 5, 0, -2, -3, 1, 0, -2, 0, -3, -2, 2, -1, -3, -2, -1, -1, -3,
{ -4, -4, -4, -4, -4, -4, -4, -4, -4, -4, -4, -4, -4, -4, -4, -4, -4,
-4, -4, -4, -4, -4, -4, 1 }, };
- static final int[][] PAM250 =
- {
+ static final int[][] PAM250 = {
{ 2, -2, 0, 0, -2, 0, 0, 1, -1, -1, -2, -1, -1, -3, 1, 1, 1, -6, -3,
0, 0, 0, 0, -8 },
{ -2, 6, 0, -1, -4, 1, -1, -3, 2, -2, -3, 3, 0, -4, 0, 0, -1, 2, -4,
// treats T and U identically. R and Y weak equivalence with AG and CTU.
// N matches any other base weakly
//
- static final int[][] DNA =
- {
- { 10, -8, -8, -8, -8, 1, 1, 1, -8, 1, 1 }, // A
+ static final int[][] DNA = { { 10, -8, -8, -8, -8, 1, 1, 1, -8, 1, 1 }, // A
{ -8, 10, -8, -8, -8, 1, 1, -8, 1, 1, 1 }, // C
{ -8, -8, 10, -8, -8, 1, 1, 1, -8, 1, 1 }, // G
{ -8, -8, -8, 10, 10, 1, 1, -8, 1, 1, 1 }, // T
}
- public static final Color[] pidColours =
- { midBlue, new Color(153, 153, 255),
+ public static final Color[] pidColours = { midBlue,
+ new Color(153, 153, 255),
// Color.lightGray,
new Color(204, 204, 255), };
- public static final float[] pidThresholds =
- { 80, 60, 40, };
+ public static final float[] pidThresholds = { 80, 60, 40, };
- public static Hashtable codonHash = new Hashtable();
+ public static Map<String, List<String>> codonHash = new HashMap<String, List<String>>();
- public static Vector Lys = new Vector();
+ private static List<String> Lys = new ArrayList<String>();
- public static Vector Asn = new Vector();
+ private static List<String> Asn = new ArrayList<String>();
- public static Vector Gln = new Vector();
+ private static List<String> Gln = new ArrayList<String>();
- public static Vector His = new Vector();
+ private static List<String> His = new ArrayList<String>();
- public static Vector Glu = new Vector();
+ private static List<String> Glu = new ArrayList<String>();
- public static Vector Asp = new Vector();
+ private static List<String> Asp = new ArrayList<String>();
- public static Vector Tyr = new Vector();
+ private static List<String> Tyr = new ArrayList<String>();
- public static Vector Thr = new Vector();
+ private static List<String> Thr = new ArrayList<String>();
- public static Vector Pro = new Vector();
+ private static List<String> Pro = new ArrayList<String>();
- public static Vector Ala = new Vector();
+ private static List<String> Ala = new ArrayList<String>();
- public static Vector Ser = new Vector();
+ private static List<String> Ser = new ArrayList<String>();
- public static Vector Arg = new Vector();
+ private static List<String> Arg = new ArrayList<String>();
- public static Vector Gly = new Vector();
+ private static List<String> Gly = new ArrayList<String>();
- public static Vector Trp = new Vector();
+ private static List<String> Trp = new ArrayList<String>();
- public static Vector Cys = new Vector();
+ private static List<String> Cys = new ArrayList<String>();
- public static Vector Ile = new Vector();
+ private static List<String> Ile = new ArrayList<String>();
- public static Vector Met = new Vector();
+ private static List<String> Met = new ArrayList<String>();
- public static Vector Leu = new Vector();
+ private static List<String> Leu = new ArrayList<String>();
- public static Vector Val = new Vector();
+ private static List<String> Val = new ArrayList<String>();
- public static Vector Phe = new Vector();
+ private static List<String> Phe = new ArrayList<String>();
- public static Vector STOP = new Vector();
+ public static List<String> STOP = new ArrayList<String>();
+
+ public static String START = "ATG";
static
{
/**
* Nucleotide Ambiguity Codes
*/
- public static final Hashtable<String, String[]> ambiguityCodes = new Hashtable<String, String[]>();
+ public static final Map<String, String[]> ambiguityCodes = new Hashtable<String, String[]>();
/**
* Codon triplets with additional symbols for unambiguous codons that include
static
{
- /**
- * 3.2. Purine (adenine or guanine): R
- *
- * R is the symbol previously recommended [1].
+ /*
+ * Ambiguity codes as per http://www.chem.qmul.ac.uk/iubmb/misc/naseq.html
*/
- ambiguityCodes.put("R", new String[]
- { "A", "G" });
+ ambiguityCodes.put("R", new String[] { "A", "G" });
+ ambiguityCodes.put("Y", new String[] { "T", "C" });
+ ambiguityCodes.put("W", new String[] { "A", "T" });
+ ambiguityCodes.put("S", new String[] { "G", "C" });
+ ambiguityCodes.put("M", new String[] { "A", "C" });
+ ambiguityCodes.put("K", new String[] { "G", "T" });
+ ambiguityCodes.put("H", new String[] { "A", "T", "C" });
+ ambiguityCodes.put("B", new String[] { "G", "T", "C" });
+ ambiguityCodes.put("V", new String[] { "G", "A", "C" });
+ ambiguityCodes.put("D", new String[] { "G", "A", "T" });
+ ambiguityCodes.put("N", new String[] { "G", "A", "T", "C" });
- /**
- * 3.3. Pyrimidine (thymine or cytosine): Y
- *
- * Y is the symbol previously recommended [1].
- */
- ambiguityCodes.put("Y", new String[]
- { "T", "C" });
- /**
- * 3.4. Adenine or thymine: W
- *
- * Although several diverse symbols have been used for this pair, (and for
- * the reciprocal pair G+C), only two symbols have a rational basis, L and
- * W: L derives from DNA density (light; G+C - heavy - would thus be H); W
- * derives from the strength of the hydrogen bonding interaction between the
- * base pairs (weak for A+T: G +C - strong - would thus be S). However, the
- * system recommended for the three-base series (not-A = B, etc., see below,
- * section 3.8) rules out H as this would be not-G. W is thus recommended.
- */
- ambiguityCodes.put("W", new String[]
- { "A", "T" });
- /**
- * 3.5. Guanine or cytosine: S
- *
- * The choice of this symbol is discussed above in section 3.4.
- */
- ambiguityCodes.put("S", new String[]
- { "G", "C" });
- /**
- * 3.6. Adenine or cytosine: M
- *
- * There are few common features between A and C. The presence of an NH2
- * group in similar positions on both bases (Fig. 1) makes possible a
- * logically derived symbol. A and N being ruled out, M (from aMino) is
- * recommended.
- *
- *
- * Fig. 1. Origin of the symbols M and K The four bases are drawn so as to
- * show the relationship between adenine and cytosine on the one hand, which
- * both have aMino groups at the ring position most distant from the point
- * of attachment to the sugar, and between guanine and thymine on the other,
- * which both have Keto groups at the corresponding position. The ring atoms
- * are numbered as recommended [24-26], although for the present purpose
- * this has the disadvantage of giving discordant numbers to the
- * corresponding positions.
- */
- ambiguityCodes.put("M", new String[]
- { "A", "C" });
- /**
- * 3.7. Guanine or thymine: K By analogy with A and C (section 3.6), both G
- * and T have Keto groups in similar positions (Fig. 1).
- */
- ambiguityCodes.put("K", new String[]
- { "G", "T" });
- /**
- * 3.8. Adenine or thymine or cytosine: H
- *
- * Not-G is the most simple means of memorising this combination and symbols
- * logically related to G were examined. F and H would both be suitable, as
- * the letters before and after G in the alphabet, but A would have no
- * equivalent to F. The use of H has historical precedence [2].
- */
- ambiguityCodes.put("H", new String[]
- { "A", "T", "C" });
- /**
- * 3.9. Guanine or cytosine or thymine: B
- *
- * Not-A as above (section 3.8).
- */
- ambiguityCodes.put("B", new String[]
- { "G", "T", "C" });
- /**
- * 3.10. Guanine or adenine or cytosine: V
- *
- * Not-T by analogy with not-G (section 3.8) would be U but this is ruled
- * out to eliminate confusion with uracil. V is the next logical choice.
- * Note that T and U may in some cases be considered to be synonyms.
- */
- ambiguityCodes.put("V", new String[]
- { "G", "A", "C" });
- /**
- * 3.11. Guanine or adenine or thymine: D
- *
- * Not-C as above (section 3.8).
- */
- ambiguityCodes.put("D", new String[]
- { "G", "A", "T" });
- /**
- * 3.12. Guanine or adenine or thymine or cytosine: N
- */
- ambiguityCodes.put("R", new String[]
- { "G", "A", "T", "C" });
// Now build codon translation table
codonHash2.put("AAA", "K");
codonHash2.put("AAG", "K");
}
else
{
- acodon[i] = new String[]
- {};
+ acodon[i] = new String[] {};
}
}
// enumerate all combinations and test for veracity of translation
if (acodon[ipos].length == 0 || tpos[ipos] < 0)
{
_acodon += codon.charAt(ipos);
- allres[ipos] = new char[]
- { codon.charAt(ipos) };
+ allres[ipos] = new char[] { codon.charAt(ipos) };
}
else
{
static
{
- Lys.addElement("AAA");
- Lys.addElement("AAG");
- Asn.addElement("AAC");
- Asn.addElement("AAT");
-
- Gln.addElement("CAA");
- Gln.addElement("CAG");
- His.addElement("CAC");
- His.addElement("CAT");
-
- Glu.addElement("GAA");
- Glu.addElement("GAG");
- Asp.addElement("GAC");
- Asp.addElement("GAT");
-
- Tyr.addElement("TAC");
- Tyr.addElement("TAT");
-
- Thr.addElement("ACA");
- Thr.addElement("ACG");
- Thr.addElement("ACC");
- Thr.addElement("ACT");
-
- Pro.addElement("CCA");
- Pro.addElement("CCG");
- Pro.addElement("CCC");
- Pro.addElement("CCT");
-
- Ala.addElement("GCA");
- Ala.addElement("GCG");
- Ala.addElement("GCC");
- Ala.addElement("GCT");
-
- Ser.addElement("TCA");
- Ser.addElement("TCG");
- Ser.addElement("TCC");
- Ser.addElement("TCT");
- Ser.addElement("AGC");
- Ser.addElement("AGT");
-
- Arg.addElement("AGA");
- Arg.addElement("AGG");
- Arg.addElement("CGA");
- Arg.addElement("CGG");
- Arg.addElement("CGC");
- Arg.addElement("CGT");
-
- Gly.addElement("GGA");
- Gly.addElement("GGG");
- Gly.addElement("GGC");
- Gly.addElement("GGT");
-
- STOP.addElement("TGA");
- STOP.addElement("TAA");
- STOP.addElement("TAG");
-
- Trp.addElement("TGG");
-
- Cys.addElement("TGC");
- Cys.addElement("TGT");
-
- Ile.addElement("ATA");
- Ile.addElement("ATC");
- Ile.addElement("ATT");
-
- Met.addElement("ATG");
-
- Leu.addElement("CTA");
- Leu.addElement("CTG");
- Leu.addElement("CTC");
- Leu.addElement("CTT");
- Leu.addElement("TTA");
- Leu.addElement("TTG");
-
- Val.addElement("GTA");
- Val.addElement("GTG");
- Val.addElement("GTC");
- Val.addElement("GTT");
-
- Phe.addElement("TTC");
- Phe.addElement("TTT");
+ Lys.add("AAA");
+ Lys.add("AAG");
+ Asn.add("AAC");
+ Asn.add("AAT");
+
+ Gln.add("CAA");
+ Gln.add("CAG");
+ His.add("CAC");
+ His.add("CAT");
+
+ Glu.add("GAA");
+ Glu.add("GAG");
+ Asp.add("GAC");
+ Asp.add("GAT");
+
+ Tyr.add("TAC");
+ Tyr.add("TAT");
+
+ Thr.add("ACA");
+ Thr.add("ACG");
+ Thr.add("ACC");
+ Thr.add("ACT");
+
+ Pro.add("CCA");
+ Pro.add("CCG");
+ Pro.add("CCC");
+ Pro.add("CCT");
+
+ Ala.add("GCA");
+ Ala.add("GCG");
+ Ala.add("GCC");
+ Ala.add("GCT");
+
+ Ser.add("TCA");
+ Ser.add("TCG");
+ Ser.add("TCC");
+ Ser.add("TCT");
+ Ser.add("AGC");
+ Ser.add("AGT");
+
+ Arg.add("AGA");
+ Arg.add("AGG");
+ Arg.add("CGA");
+ Arg.add("CGG");
+ Arg.add("CGC");
+ Arg.add("CGT");
+
+ Gly.add("GGA");
+ Gly.add("GGG");
+ Gly.add("GGC");
+ Gly.add("GGT");
+
+ STOP.add("TGA");
+ STOP.add("TAA");
+ STOP.add("TAG");
+
+ Trp.add("TGG");
+
+ Cys.add("TGC");
+ Cys.add("TGT");
+
+ Ile.add("ATA");
+ Ile.add("ATC");
+ Ile.add("ATT");
+
+ Met.add("ATG");
+
+ Leu.add("CTA");
+ Leu.add("CTG");
+ Leu.add("CTC");
+ Leu.add("CTT");
+ Leu.add("TTA");
+ Leu.add("TTG");
+
+ Val.add("GTA");
+ Val.add("GTG");
+ Val.add("GTC");
+ Val.add("GTT");
+
+ Phe.add("TTC");
+ Phe.add("TTT");
}
// Stores residue codes/names and colours and other things
propMatrixF[i][j] = 0;
propMatrixPos[i][j] = 0;
propMatrixEpos[i][j] = 0;
- for (Enumeration<String> en = propHash.keys(); en
- .hasMoreElements();)
+ for (Enumeration<String> en = propHash.keys(); en.hasMoreElements();)
{
String ph = en.nextElement();
Map<String, Integer> pph = (Map<String, Integer>) propHash
// scoreMatrices.put("Conservation EnhPos", new
// ScoreMatrix("Conservation EnhPos",propMatrixEpos,0));
scoreMatrices.put("PID", new PIDScoreModel());
+ scoreMatrices.put("Displayed Features", new FeatureScoreModel());
}
private ResidueProperties()
return hyd;
}
- public static Hashtable getAA3Hash()
+ public static Map<String, Integer> getAA3Hash()
{
return aa3Hash;
}
return _codonTranslate(lccodon);
}
String cdn = codonHash2.get(lccodon.toUpperCase());
- if (cdn != null && cdn.equals("*"))
+ if ("*".equals(cdn))
{
return "STOP";
}
{
return "X";
}
- Enumeration e = codonHash.keys();
-
- while (e.hasMoreElements())
+ for (String key : codonHash.keySet())
{
- String key = (String) e.nextElement();
- Vector tmp = (Vector) codonHash.get(key);
-
- if (tmp.contains(codon))
+ if (codonHash.get(key).contains(codon))
{
return key;
}
* Used by getRNASecStrucState
*
*/
- public static Hashtable toRNAssState;
+ public static Hashtable<String, String> toRNAssState;
+
+ public static boolean RNAcloseParen[] = new boolean[255];
static
{
toRNAssState = new Hashtable<String, String>();
toRNAssState.put("y", "Y");
toRNAssState.put("Z", "Z");
toRNAssState.put("z", "Z");
+ for (int p = 0; p < RNAcloseParen.length; p++)
+ {
+ RNAcloseParen[p] = false;
+ }
+ for (String k : toRNAssState.keySet())
+ {
+ RNAcloseParen[k.charAt(0)] = k.charAt(0) != toRNAssState.get(k)
+ .charAt(0);
+ }
+ }
+ static
+ {
+ modifications.put("MSE", "MET"); // Selenomethionine
+ // the rest tbc; from
+ // http://sourceforge.net/p/jmol/mailman/message/12833570/
+ // modifications.put("CSE", "CYS"); // Selenocysteine
+ // modifications.put("PTR", "TYR"); // Phosphotyrosine
+ // modifications.put("SEP", "SER"); // Phosphoserine
+ // modifications.put("HYP", "PRO"); // 4-hydroxyproline
+ // modifications.put("5HP", "GLU"); // Pyroglutamic acid; 5-hydroxyproline
+ // modifications.put("PCA", "GLU"); // Pyroglutamic acid
+ // modifications.put("LYZ", "LYS"); // 5-hydroxylysine
+ }
+
+ public static String getCanonicalAminoAcid(String aa)
+ {
+ String canonical = modifications.get(aa);
+ return canonical == null ? aa : canonical;
}
/**
String ssc = ssstring.substring(i, i + 1);
if (toRNAssState.containsKey(ssc))
{
- ss.append((String) toRNAssState.get(ssc));
+ // valid ss character - so return it
+ ss.append(ssc); // (String) toRNAssState.get(ssc));
}
else
{
return ss.toString();
}
+ public static boolean isCloseParenRNA(char dc)
+ {
+ return RNAcloseParen[dc];
+ }
+
// main method generates perl representation of residue property hash
// / cut here
public static void main(String[] args)
}
System.out.println("};");
}
+
// to here
+ /**
+ * Returns a list of residue characters for the specified inputs
+ *
+ * @param nucleotide
+ * @param includeAmbiguous
+ * @return
+ */
+ public static List<String> getResidues(boolean nucleotide,
+ boolean includeAmbiguous)
+ {
+ List<String> result = new ArrayList<String>();
+ if (nucleotide)
+ {
+ for (String nuc : nucleotideName.keySet())
+ {
+ int val = nucleotideIndex[nuc.charAt(0)];
+ if ((!includeAmbiguous && val > 4) || (val >= maxNucleotideIndex))
+ {
+ continue;
+ }
+ nuc = nuc.toUpperCase();
+ if (!result.contains(nuc))
+ {
+ result.add(nuc);
+ }
+ }
+ }
+ else
+ {
+ /*
+ * Peptide
+ */
+ for (String res : aa3Hash.keySet())
+ {
+ int index = aa3Hash.get(res).intValue();
+ if ((!includeAmbiguous && index >= 20) || index >= maxProteinIndex)
+ {
+ continue;
+ }
+ res = res.toUpperCase();
+ if (!result.contains(res))
+ {
+ result.add(res);
+ }
+ }
+ }
+
+ return result;
+ }
+
+ /**
+ * Returns the single letter code for a three letter code, or '0' if not known
+ *
+ * @param threeLetterCode
+ * not case sensitive
+ * @return
+ */
+ public static char getSingleCharacterCode(String threeLetterCode)
+ {
+ if (threeLetterCode == null)
+ {
+ return '0';
+ }
+ Integer index = ResidueProperties.aa3Hash.get(threeLetterCode
+ .toUpperCase());
+ return index == null ? '0' : aa[index].charAt(0);
+ }
}