Difference between revisions of "User:Chase-san/StatBufferSet"
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(→chase.s2.stat.StatData: Updated for new range support.) |
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[[Category:Code Snippets|StatBufferSet]] | [[Category:Code Snippets|StatBufferSet]] | ||
This is a set of stat buffer configuration to make all those nightmares of dealing with and updating multiple multidimensional VCS bins, go away. | This is a set of stat buffer configuration to make all those nightmares of dealing with and updating multiple multidimensional VCS bins, go away. | ||
+ | |||
+ | This makes use of my [[User:Chase-san/VDA|Variable Dimension Array]] so be sure to get a copy of that as well. | ||
+ | |||
+ | This and all my other code in which I display on the robowiki falls under the [http://en.wikipedia.org/wiki/Zlib_License ZLIB License]. | ||
Line 61: | Line 65: | ||
package chase.s2.stat; | package chase.s2.stat; | ||
− | import | + | import chase.s2.misc.VDA; |
/** | /** | ||
Line 73: | Line 77: | ||
public class StatBuffer { | public class StatBuffer { | ||
protected static final int scanWidth = 1; | protected static final int scanWidth = 1; | ||
− | + | ||
/** Handing the VDA manually is dangerous, and could wipe out all your data */ | /** Handing the VDA manually is dangerous, and could wipe out all your data */ | ||
private VDA<double[]> _binSet; | private VDA<double[]> _binSet; | ||
Line 80: | Line 84: | ||
/** This is fine, since java can handle jagged arrays */ | /** This is fine, since java can handle jagged arrays */ | ||
public double[][] _splits; | public double[][] _splits; | ||
− | + | ||
+ | public double halfLife = -1; | ||
+ | |||
/** | /** | ||
* Constructs a new buffer | * Constructs a new buffer | ||
− | * @param splits The data defining the data splits, usually a jagged array | + | * |
− | * @param dataIndex the index of the raw stats each split is on | + | * @param splits |
− | * @param binTotal total number of indexes for this buffer | + | * The data defining the data splits, usually a jagged array |
+ | * @param dataIndex | ||
+ | * the index of the raw stats each split is on | ||
+ | * @param binTotal | ||
+ | * total number of indexes for this buffer | ||
*/ | */ | ||
public StatBuffer(double[][] splits, int[] dataIndex, int binTotal) { | public StatBuffer(double[][] splits, int[] dataIndex, int binTotal) { | ||
Line 92: | Line 102: | ||
_dataIndex = dataIndex; | _dataIndex = dataIndex; | ||
_splits = splits; | _splits = splits; | ||
− | + | ||
int[] dimensions = new int[Math.max(1, splits.length)]; | int[] dimensions = new int[Math.max(1, splits.length)]; | ||
dimensions[0] = 1; | dimensions[0] = 1; | ||
− | for(int i=0; i<splits.length; ++i) | + | for (int i = 0; i < splits.length; ++i) |
dimensions[i] = splits[i].length + 1; | dimensions[i] = splits[i].length + 1; | ||
− | + | ||
_binSet = new VDA<double[]>(dimensions); | _binSet = new VDA<double[]>(dimensions); | ||
− | + | } | |
− | + | ||
− | + | /** | |
− | + | * Initializes a given location in the stat buffer, used for memory | |
− | + | * conservation via lazy initialization. | |
− | + | */ | |
− | + | public void initialize(int[] pos) { | |
+ | double[] d = _binSet.get(pos); | ||
+ | if (d == null) { | ||
+ | _binSet.set(new double[_binTotal], pos); | ||
} | } | ||
} | } | ||
− | + | ||
/** | /** | ||
* Constructs a new stat buffer, using the lazy SplitSet | * Constructs a new stat buffer, using the lazy SplitSet | ||
− | * @param ss SplitSet to use | + | * |
− | * @param binTotal total number of indexes for this buffer | + | * @param ss |
+ | * SplitSet to use | ||
+ | * @param binTotal | ||
+ | * total number of indexes for this buffer | ||
*/ | */ | ||
public StatBuffer(SplitSet ss, int binTotal) { | public StatBuffer(SplitSet ss, int binTotal) { | ||
− | this(ss.getSplitSet(),ss.getIndexSet(),binTotal); | + | this(ss.getSplitSet(), ss.getIndexSet(), binTotal); |
} | } | ||
− | + | ||
/** | /** | ||
* This creates a flat, single dimension stat buffer. | * This creates a flat, single dimension stat buffer. | ||
− | * @param binTotal total number of indexes for this buffer | + | * |
+ | * @param binTotal | ||
+ | * total number of indexes for this buffer | ||
*/ | */ | ||
public StatBuffer(int binTotal) { | public StatBuffer(int binTotal) { | ||
this(new double[0][0], new int[0], binTotal); | this(new double[0][0], new int[0], binTotal); | ||
} | } | ||
− | + | ||
/** | /** | ||
− | * This method splits the raw data as defined by the data index | + | * This method splits the raw data as defined by the data index and split |
− | * | + | * information. It outputs a data array which can be fed to the VDA to get |
− | + | * the desired bin set. | |
− | * @param data raw data | + | * |
+ | * @param data | ||
+ | * raw data | ||
* @return data indexes | * @return data indexes | ||
*/ | */ | ||
public int[] convertData(StatData data) { | public int[] convertData(StatData data) { | ||
int[] indexes = new int[Math.max(1, _dataIndex.length)]; | int[] indexes = new int[Math.max(1, _dataIndex.length)]; | ||
− | if(_splits.length == 0) return indexes; | + | if (_splits.length == 0) |
− | for(int i = 0; i < indexes.length; ++i) { | + | return indexes; |
+ | for (int i = 0; i < indexes.length; ++i) { | ||
int index = 0; | int index = 0; | ||
− | for(;index < _splits[i].length; ++index) { | + | for (; index < _splits[i].length; ++index) { |
− | if(data._data[_dataIndex[i]] < | + | if (data._data[_dataIndex[i]] < _splits[i][index]) |
+ | break; | ||
} | } | ||
indexes[i] = index; | indexes[i] = index; | ||
Line 145: | Line 167: | ||
return indexes; | return indexes; | ||
} | } | ||
− | + | ||
/** | /** | ||
* Gets the individual stat buffer for the give data. | * Gets the individual stat buffer for the give data. | ||
*/ | */ | ||
public double[] getStatBin(StatData data) { | public double[] getStatBin(StatData data) { | ||
− | return _binSet.get( | + | int[] indexes = convertData(data); |
+ | initialize(indexes); | ||
+ | return _binSet.get(indexes); | ||
} | } | ||
− | + | ||
+ | /** | ||
+ | * Sets the decay half-life of this buffer anything < 0 is infinite. | ||
+ | */ | ||
+ | public void setHalflife(double hlife) { | ||
+ | if (hlife < 0) { | ||
+ | halfLife = -1; | ||
+ | } else { | ||
+ | halfLife = hlife; | ||
+ | } | ||
+ | } | ||
+ | |||
/** | /** | ||
* Updates this stat buffer with the given raw data | * Updates this stat buffer with the given raw data | ||
Line 159: | Line 194: | ||
double[] bins = getStatBin(data); | double[] bins = getStatBin(data); | ||
double index = GFToIndex(data._gf, _binTotal); | double index = GFToIndex(data._gf, _binTotal); | ||
− | updateBin(bins, index, weight); | + | |
+ | if (halfLife > 0) { | ||
+ | if (data.range) { | ||
+ | double end = GFToIndex(data._max, _binTotal); | ||
+ | updateBinRollingRange(bins, index, end, weight, halfLife); | ||
+ | } else { | ||
+ | updateBinRolling(bins, index, weight, halfLife); | ||
+ | } | ||
+ | } else { | ||
+ | if (data.range) { | ||
+ | double end = GFToIndex(data._max, _binTotal); | ||
+ | updateBinRange(bins, index, end, weight); | ||
+ | } else { | ||
+ | updateBin(bins, index, weight); | ||
+ | } | ||
+ | } | ||
} | } | ||
− | + | ||
/** | /** | ||
* Gets the best bin from the raw data | * Gets the best bin from the raw data | ||
Line 169: | Line 219: | ||
return getBestIndex(bins, scanWidth); | return getBestIndex(bins, scanWidth); | ||
} | } | ||
− | + | ||
/** | /** | ||
* Gets the best guessfactor from the raw data | * Gets the best guessfactor from the raw data | ||
*/ | */ | ||
public double getBestGF(StatData data) { | public double getBestGF(StatData data) { | ||
− | return indexToGF(getBestIndex(data),_binTotal); | + | return indexToGF(getBestIndex(data), _binTotal); |
} | } | ||
− | + | ||
+ | /** | ||
+ | * return the array that backs the VDA | ||
+ | */ | ||
+ | public Object[] getBackBuffer() { | ||
+ | return _binSet.getBackingArray(); | ||
+ | } | ||
+ | |||
/** | /** | ||
− | * TODO: Replace this with some kind of externalized update method. | + | * TODO: Replace this with some kind of externalized update method. That way |
− | * | + | * it is easier to replace with rolling and different distributions |
*/ | */ | ||
public static final void updateBin(double[] bin, double index, double weight) { | public static final void updateBin(double[] bin, double index, double weight) { | ||
− | for(int i= | + | int iIndex = (int) Math.round(index); |
+ | for (int i = iIndex; i < bin.length && i <= iIndex + 1; ++i) { | ||
double amount = Math.abs(i - index); | double amount = Math.abs(i - index); | ||
− | if(amount | + | if (amount < 1e-6) |
− | if(amount > 0 && amount < 1) | + | bin[i] += weight; |
+ | else if (amount > 0 && amount < 1) | ||
bin[i] += amount * weight; | bin[i] += amount * weight; | ||
+ | } | ||
+ | } | ||
+ | |||
+ | /** | ||
+ | * Updates a bin set based on a gf range. | ||
+ | */ | ||
+ | public static final void updateBinRange(double[] bin, double start, | ||
+ | double end, double weight) { | ||
+ | for (int i = (int) (start); i < bin.length && i <= (int) (end + 1); ++i) { | ||
+ | if (i >= start && i <= end) { | ||
+ | bin[i] += weight; | ||
+ | } else { | ||
+ | bin[i] += Math.min(Math.abs(i - start), Math.abs(i - end)) | ||
+ | * weight; | ||
} | } | ||
} | } | ||
} | } | ||
− | + | ||
+ | /** | ||
+ | * Updates a bin set, with rolling averages. | ||
+ | */ | ||
+ | public static final void updateBinRolling(double[] bin, double index, | ||
+ | double weight, double halflife) { | ||
+ | double decay = computeDecayRate(halflife); | ||
+ | for (int i = 0; i < bin.length; ++i) | ||
+ | bin[i] *= decay; | ||
+ | updateBin(bin, index, weight * (1 - decay)); | ||
+ | } | ||
+ | |||
+ | /** | ||
+ | * Updates a bin set, with rolling averages and a gf range. | ||
+ | */ | ||
+ | public static final void updateBinRollingRange(double[] bin, double start, | ||
+ | double end, double weight, double halflife) { | ||
+ | double decay = computeDecayRate(halflife); | ||
+ | for (int i = 0; i < bin.length; ++i) | ||
+ | bin[i] *= decay; | ||
+ | updateBinRange(bin, start, end, weight * (1 - decay)); | ||
+ | } | ||
+ | |||
/** | /** | ||
− | * Static method used to find the best index. Width is number | + | * Static method used to find the best index. Width is number of extra bins |
− | * | + | * to each side to test. |
*/ | */ | ||
public static final int getBestIndex(double[] bin, int width) { | public static final int getBestIndex(double[] bin, int width) { | ||
− | double[] score = getBinScores(bin,width); | + | double[] score = getBinScores(bin, width); |
− | int bestIndex = | + | int bestIndex = (bin.length - 1) / 2; /* TODO: This could be problematic */ |
− | for(int i=0; i<bin.length; ++i) | + | for (int i = 0; i < bin.length; ++i) |
− | if(score[i] > score[bestIndex]) | + | if (score[i] > score[bestIndex]) |
bestIndex = i; | bestIndex = i; | ||
return bestIndex; | return bestIndex; | ||
} | } | ||
− | + | ||
/** | /** | ||
* Gets the scores for each bin in the given stat bin. | * Gets the scores for each bin in the given stat bin. | ||
Line 209: | Line 304: | ||
protected static final double[] getBinScores(double[] bin, int width) { | protected static final double[] getBinScores(double[] bin, int width) { | ||
double[] scores = new double[bin.length]; | double[] scores = new double[bin.length]; | ||
− | for(int i=0; i<bin.length; ++i) { | + | for (int i = 0; i < bin.length; ++i) { |
double score = 0; | double score = 0; | ||
− | //It is a little complicated in there, but things will | + | // It is a little complicated in there, but things will |
− | // | + | // never go out of bounds |
− | for(int j=-width; j<width+1; ++j) { | + | for (int j = -width; j < width + 1; ++j) { |
int abs = Math.abs(j) + 1; | int abs = Math.abs(j) + 1; | ||
− | if(i+j < 0 || i+j >= bin.length) { | + | if (i + j < 0 || i + j >= bin.length) { |
− | if(i == 0 || i == bin.length - 1) { | + | if (i == 0 || i == bin.length - 1) { |
score += bin[i - j] / abs; | score += bin[i - j] / abs; | ||
} else { | } else { | ||
Line 230: | Line 325: | ||
return scores; | return scores; | ||
} | } | ||
− | + | ||
/** | /** | ||
* Converts a bin index to a guessfactor based on total number of bins. | * Converts a bin index to a guessfactor based on total number of bins. | ||
*/ | */ | ||
public static final double indexToGF(int index, int bins) { | public static final double indexToGF(int index, int bins) { | ||
− | index = Math.min(Math.max(0,index),bins - 1); | + | index = Math.min(Math.max(0, index), bins - 1); |
− | double half = (bins-1.0)/2.0; | + | double half = (bins - 1.0) / 2.0; |
return (index / half) - 1.0; | return (index / half) - 1.0; | ||
} | } | ||
− | + | ||
/** | /** | ||
* Converts a guessfactor to a bin index, based on number of bins. This | * Converts a guessfactor to a bin index, based on number of bins. This | ||
− | * returns a double, incase there is any need to know how much it over | + | * returns a double, incase there is any need to know how much it over hangs |
− | * | + | * each bin. Cast to an int for the raw information. |
*/ | */ | ||
public static final double GFToIndex(double gf, int bins) { | public static final double GFToIndex(double gf, int bins) { | ||
− | gf = Math.min(Math.max(-1.0,gf),1.0) + 1.0; | + | gf = Math.min(Math.max(-1.0, gf), 1.0) + 1.0; |
− | double half = (bins-1.0)/2.0; | + | double half = (bins - 1.0) / 2.0; |
return gf * half; | return gf * half; | ||
+ | } | ||
+ | |||
+ | /** | ||
+ | * Computation of decay rate | ||
+ | */ | ||
+ | public static double computeDecayRate(double halfLife) { | ||
+ | return Math.exp(Math.log(0.5) / halfLife); | ||
} | } | ||
} | } | ||
Line 268: | Line 370: | ||
double weight; | double weight; | ||
} | } | ||
− | + | ||
private List<StatItem> autobin = new ArrayList<StatItem>(); | private List<StatItem> autobin = new ArrayList<StatItem>(); | ||
− | + | ||
/** | /** | ||
* Add a stat buffer to this buffer set. | * Add a stat buffer to this buffer set. | ||
Line 280: | Line 382: | ||
autobin.add(si); | autobin.add(si); | ||
} | } | ||
− | + | ||
+ | /** | ||
+ | * Get a stat buffer from this buffer set. | ||
+ | */ | ||
+ | public StatBuffer get(int index) { | ||
+ | return autobin.get(index).buffer; | ||
+ | } | ||
+ | |||
+ | /** | ||
+ | * Remove a statbuffer from this buffer set | ||
+ | */ | ||
+ | public void remove(int index) { | ||
+ | autobin.remove(index); | ||
+ | } | ||
+ | |||
+ | /** | ||
+ | * Returns the number of stat buffers. | ||
+ | */ | ||
+ | public int size() { | ||
+ | return autobin.size(); | ||
+ | } | ||
+ | |||
/** | /** | ||
* Gets the single best GF from each StatBuffer. | * Gets the single best GF from each StatBuffer. | ||
Line 287: | Line 410: | ||
double[] output = new double[autobin.size()]; | double[] output = new double[autobin.size()]; | ||
int i = 0; | int i = 0; | ||
− | for(StatItem s : autobin) { | + | for (StatItem s : autobin) { |
output[i++] = s.buffer.getBestGF(data); | output[i++] = s.buffer.getBestGF(data); | ||
} | } | ||
return output; | return output; | ||
} | } | ||
− | + | ||
/** | /** | ||
* Gets a list of all the bins for the raw data. | * Gets a list of all the bins for the raw data. | ||
Line 299: | Line 422: | ||
double[][] output = new double[autobin.size()][]; | double[][] output = new double[autobin.size()][]; | ||
int i = 0; | int i = 0; | ||
− | for(StatItem s : autobin) { | + | for (StatItem s : autobin) { |
output[i++] = s.buffer.getStatBin(data); | output[i++] = s.buffer.getStatBin(data); | ||
} | } | ||
return output; | return output; | ||
} | } | ||
− | + | ||
/** | /** | ||
* Gets the list of weights. | * Gets the list of weights. | ||
Line 311: | Line 434: | ||
double[] output = new double[autobin.size()]; | double[] output = new double[autobin.size()]; | ||
int i = 0; | int i = 0; | ||
− | for(StatItem s : autobin) { | + | for (StatItem s : autobin) { |
output[i++] = s.weight; | output[i++] = s.weight; | ||
} | } | ||
return output; | return output; | ||
} | } | ||
− | + | ||
+ | /** | ||
+ | * Gets the combined score data for the given stat data. | ||
+ | */ | ||
public double[] getCombinedScoreData(StatData sd) { | public double[] getCombinedScoreData(StatData sd) { | ||
double[][] data = getBinList(sd); | double[][] data = getBinList(sd); | ||
double[] weights = getWeightList(); | double[] weights = getWeightList(); | ||
− | return getCombinedScoreData(data,weights); | + | return getCombinedScoreData(data, weights); |
} | } | ||
− | + | ||
/** | /** | ||
− | * This combines the data over all the bins in such | + | * This combines the data over all the bins in such a way that it can be |
− | + | * read easily as if it were a single stat bin. | |
− | |||
*/ | */ | ||
private double[] getCombinedScoreData(double[][] data, double[] weights) { | private double[] getCombinedScoreData(double[][] data, double[] weights) { | ||
− | if(weights.length != data.length) | + | if (weights.length != data.length) |
− | throw new IllegalArgumentException("Data length and weights length must match."); | + | throw new IllegalArgumentException( |
− | + | "Data length and weights length must match."); | |
+ | |||
/* Determine the longest and shortest bin set */ | /* Determine the longest and shortest bin set */ | ||
int shortest = Integer.MAX_VALUE; | int shortest = Integer.MAX_VALUE; | ||
int longest = Integer.MIN_VALUE; | int longest = Integer.MIN_VALUE; | ||
− | for(double[] d : data) { | + | for (double[] d : data) { |
− | if(d.length > longest) longest = d.length; | + | if (d.length > longest) |
− | if(d.length < shortest) shortest = d.length; | + | longest = d.length; |
+ | if (d.length < shortest) | ||
+ | shortest = d.length; | ||
} | } | ||
− | + | ||
/* Get each of their scores, and record the largest of each. */ | /* Get each of their scores, and record the largest of each. */ | ||
double[][] score = new double[data.length][]; | double[][] score = new double[data.length][]; | ||
double[] largest = new double[data.length]; | double[] largest = new double[data.length]; | ||
− | for(int i=0; i<data.length; ++i) { | + | for (int i = 0; i < data.length; ++i) { |
score[i] = StatBuffer.getBinScores(data[i], StatBuffer.scanWidth); | score[i] = StatBuffer.getBinScores(data[i], StatBuffer.scanWidth); | ||
− | for(int j=0;j<score[i].length;++j) | + | for (int j = 0; j < score[i].length; ++j) |
− | if(score[i][j] > largest[i]) | + | if (score[i][j] > largest[i]) |
− | largest[i] = score[i][j]; | + | largest[i] = score[i][j]; |
} | } | ||
− | + | ||
/* Equalize each of the stat bins */ | /* Equalize each of the stat bins */ | ||
− | for(int i=0; i<data.length; ++i) | + | for (int i = 0; i < data.length; ++i) |
− | for(int j=0;j<score[i].length;++j) | + | for (int j = 0; j < score[i].length; ++j) |
score[i][j] /= largest[i]; | score[i][j] /= largest[i]; | ||
− | + | ||
/* If they are equal, take the easy route */ | /* If they are equal, take the easy route */ | ||
− | if(shortest == longest) { | + | if (shortest == longest) { |
largest = new double[shortest]; | largest = new double[shortest]; | ||
− | for(int i=0; i<data.length; ++i) | + | for (int i = 0; i < data.length; ++i) |
− | for(int j=0;j<shortest;++j) | + | for (int j = 0; j < shortest; ++j) |
− | largest[j] = data[i][j] * weights[i]; | + | largest[j] += data[i][j] * weights[i]; |
− | + | ||
return largest; | return largest; | ||
} | } | ||
− | + | ||
/* Otherwise we have to do things the 'hard' way! */ | /* Otherwise we have to do things the 'hard' way! */ | ||
/* We use the longest and combine the sums from the others, based on gf */ | /* We use the longest and combine the sums from the others, based on gf */ | ||
largest = new double[longest]; | largest = new double[longest]; | ||
− | for(int i=0; i<data.length; ++i) { | + | for (int i = 0; i < data.length; ++i) { |
double[] tmpSum = new double[longest]; | double[] tmpSum = new double[longest]; | ||
/* Get the gf for the new length and multiply it by the old weight */ | /* Get the gf for the new length and multiply it by the old weight */ | ||
− | for(int j=0; j<score[i].length; ++j) { | + | for (int j = 0; j < score[i].length; ++j) { |
− | double index = StatBuffer.GFToIndex(StatBuffer.indexToGF(j, score[i].length), longest); | + | double index = StatBuffer.GFToIndex(StatBuffer.indexToGF(j, |
+ | score[i].length), longest); | ||
StatBuffer.updateBin(tmpSum, index, score[i][j]); | StatBuffer.updateBin(tmpSum, index, score[i][j]); | ||
} | } | ||
/* Add to output buffer */ | /* Add to output buffer */ | ||
− | for(int j=0; j<longest; ++j) { | + | for (int j = 0; j < longest; ++j) { |
largest[j] += tmpSum[j] * weights[i]; | largest[j] += tmpSum[j] * weights[i]; | ||
} | } | ||
} | } | ||
− | + | ||
return largest; | return largest; | ||
} | } | ||
− | + | ||
/** | /** | ||
* Gets the best GF based on weights. | * Gets the best GF based on weights. | ||
Line 389: | Line 518: | ||
public double getBestGF(StatData data) { | public double getBestGF(StatData data) { | ||
double[] score = getCombinedScoreData(data); | double[] score = getCombinedScoreData(data); | ||
− | int bestIndex = | + | int bestIndex = (score.length - 1) / 2; |
− | for(int i=0; i<score.length; ++i) | + | for (int i = 0; i < score.length; ++i) |
− | if(score[i] > score[bestIndex]) | + | if (score[i] > score[bestIndex]) |
bestIndex = i; | bestIndex = i; | ||
return StatBuffer.indexToGF(bestIndex, score.length); | return StatBuffer.indexToGF(bestIndex, score.length); | ||
} | } | ||
− | + | ||
/** | /** | ||
* Updates this stat buffer handler with the given raw data | * Updates this stat buffer handler with the given raw data | ||
*/ | */ | ||
public void update(StatData data, double weight) { | public void update(StatData data, double weight) { | ||
− | for(StatItem s : autobin) { | + | for (StatItem s : autobin) { |
s.buffer.update(data, weight); | s.buffer.update(data, weight); | ||
} | } | ||
} | } | ||
− | + | } | |
− | |||
</syntaxhighlight> | </syntaxhighlight> | ||
Line 459: | Line 587: | ||
*/ | */ | ||
public class StatData { | public class StatData { | ||
− | public double _data[], _gf; | + | public double _data[], _gf, _max; |
+ | public boolean range; | ||
public StatData(double[] data, double gf) { | public StatData(double[] data, double gf) { | ||
_data = data; | _data = data; | ||
_gf = gf; | _gf = gf; | ||
+ | range = false; | ||
+ | } | ||
+ | public StatData(double[] data, double min, double max) { | ||
+ | _data = data; | ||
+ | _gf = min; | ||
+ | _max = max; | ||
+ | range = true; | ||
} | } | ||
} | } | ||
</syntaxhighlight> | </syntaxhighlight> |
Latest revision as of 00:23, 9 July 2010
This is a set of stat buffer configuration to make all those nightmares of dealing with and updating multiple multidimensional VCS bins, go away.
This makes use of my Variable Dimension Array so be sure to get a copy of that as well.
This and all my other code in which I display on the robowiki falls under the ZLIB License.
How to use, the easy way.
//...
//In your setup.
SplitSet sset = new SplitSet();
//We add a split for the Lateral Velocity
sset.add(new double[]{2.0, 6.0}, 1);
//We add a split for the time change.
sset.add(new double[]{5, 12, 24, 46},2);
//We add a split for the distance
sset.add(new double[]{150.0, 300.0, 450.0}, 0);
//Notice how they do not have to be in order
//Create a stat buffer with 41 bins, based on our buffer set
StatBuffer sb = new StatBuffer(sset, 41);
//Create a segmentless stat buffer with 31 bins. You can have different number of bins!
StatBuffer sb2 = new StatBuffer(31);
StatBufferSet sbs = new StatBufferSet();
sbs.add(sb2, 1.0); //Unsegmented, it has a low weight.
sbs.add(sb, 100.0); //Segemented, it has a high weight.
// ...
//In your aiming
//The data we use
double[] data = new double[]{
enemyDistance,
absLateralVelocity,
timeSinceLastVelChange
};
StatData sd = new StatData(data, 0);
double gf = sbs.getBestGF(sd);
// ...
//In your wave
StatData updateSD = new StatData(data, gf);
if(realWave)
sbs.update(updateSD, 50);
else
sbs.update(updateSD, 1);
Keep in mind you can add buffers to it at any time, with very little work you can also remove buffers. This could be very useful for dynamic segmentation!
Contents
chase.s2.stat.StatBuffer
package chase.s2.stat;
import chase.s2.misc.VDA;
/**
* This is a visit count stat buffer. However, it is such a buffer where it may
* have any number of segmentation or dimensionality.
*
* For those uninformed, this is part of a statistical data mining system.
*
* @author Chase
*/
public class StatBuffer {
protected static final int scanWidth = 1;
/** Handing the VDA manually is dangerous, and could wipe out all your data */
private VDA<double[]> _binSet;
public int _binTotal;
public int[] _dataIndex;
/** This is fine, since java can handle jagged arrays */
public double[][] _splits;
public double halfLife = -1;
/**
* Constructs a new buffer
*
* @param splits
* The data defining the data splits, usually a jagged array
* @param dataIndex
* the index of the raw stats each split is on
* @param binTotal
* total number of indexes for this buffer
*/
public StatBuffer(double[][] splits, int[] dataIndex, int binTotal) {
/* TODO: splits and dataIndex lengths don't equal throw exception */
_binTotal = binTotal;
_dataIndex = dataIndex;
_splits = splits;
int[] dimensions = new int[Math.max(1, splits.length)];
dimensions[0] = 1;
for (int i = 0; i < splits.length; ++i)
dimensions[i] = splits[i].length + 1;
_binSet = new VDA<double[]>(dimensions);
}
/**
* Initializes a given location in the stat buffer, used for memory
* conservation via lazy initialization.
*/
public void initialize(int[] pos) {
double[] d = _binSet.get(pos);
if (d == null) {
_binSet.set(new double[_binTotal], pos);
}
}
/**
* Constructs a new stat buffer, using the lazy SplitSet
*
* @param ss
* SplitSet to use
* @param binTotal
* total number of indexes for this buffer
*/
public StatBuffer(SplitSet ss, int binTotal) {
this(ss.getSplitSet(), ss.getIndexSet(), binTotal);
}
/**
* This creates a flat, single dimension stat buffer.
*
* @param binTotal
* total number of indexes for this buffer
*/
public StatBuffer(int binTotal) {
this(new double[0][0], new int[0], binTotal);
}
/**
* This method splits the raw data as defined by the data index and split
* information. It outputs a data array which can be fed to the VDA to get
* the desired bin set.
*
* @param data
* raw data
* @return data indexes
*/
public int[] convertData(StatData data) {
int[] indexes = new int[Math.max(1, _dataIndex.length)];
if (_splits.length == 0)
return indexes;
for (int i = 0; i < indexes.length; ++i) {
int index = 0;
for (; index < _splits[i].length; ++index) {
if (data._data[_dataIndex[i]] < _splits[i][index])
break;
}
indexes[i] = index;
}
return indexes;
}
/**
* Gets the individual stat buffer for the give data.
*/
public double[] getStatBin(StatData data) {
int[] indexes = convertData(data);
initialize(indexes);
return _binSet.get(indexes);
}
/**
* Sets the decay half-life of this buffer anything < 0 is infinite.
*/
public void setHalflife(double hlife) {
if (hlife < 0) {
halfLife = -1;
} else {
halfLife = hlife;
}
}
/**
* Updates this stat buffer with the given raw data
*/
public void update(StatData data, double weight) {
double[] bins = getStatBin(data);
double index = GFToIndex(data._gf, _binTotal);
if (halfLife > 0) {
if (data.range) {
double end = GFToIndex(data._max, _binTotal);
updateBinRollingRange(bins, index, end, weight, halfLife);
} else {
updateBinRolling(bins, index, weight, halfLife);
}
} else {
if (data.range) {
double end = GFToIndex(data._max, _binTotal);
updateBinRange(bins, index, end, weight);
} else {
updateBin(bins, index, weight);
}
}
}
/**
* Gets the best bin from the raw data
*/
public int getBestIndex(StatData data) {
double[] bins = getStatBin(data);
return getBestIndex(bins, scanWidth);
}
/**
* Gets the best guessfactor from the raw data
*/
public double getBestGF(StatData data) {
return indexToGF(getBestIndex(data), _binTotal);
}
/**
* return the array that backs the VDA
*/
public Object[] getBackBuffer() {
return _binSet.getBackingArray();
}
/**
* TODO: Replace this with some kind of externalized update method. That way
* it is easier to replace with rolling and different distributions
*/
public static final void updateBin(double[] bin, double index, double weight) {
int iIndex = (int) Math.round(index);
for (int i = iIndex; i < bin.length && i <= iIndex + 1; ++i) {
double amount = Math.abs(i - index);
if (amount < 1e-6)
bin[i] += weight;
else if (amount > 0 && amount < 1)
bin[i] += amount * weight;
}
}
/**
* Updates a bin set based on a gf range.
*/
public static final void updateBinRange(double[] bin, double start,
double end, double weight) {
for (int i = (int) (start); i < bin.length && i <= (int) (end + 1); ++i) {
if (i >= start && i <= end) {
bin[i] += weight;
} else {
bin[i] += Math.min(Math.abs(i - start), Math.abs(i - end))
* weight;
}
}
}
/**
* Updates a bin set, with rolling averages.
*/
public static final void updateBinRolling(double[] bin, double index,
double weight, double halflife) {
double decay = computeDecayRate(halflife);
for (int i = 0; i < bin.length; ++i)
bin[i] *= decay;
updateBin(bin, index, weight * (1 - decay));
}
/**
* Updates a bin set, with rolling averages and a gf range.
*/
public static final void updateBinRollingRange(double[] bin, double start,
double end, double weight, double halflife) {
double decay = computeDecayRate(halflife);
for (int i = 0; i < bin.length; ++i)
bin[i] *= decay;
updateBinRange(bin, start, end, weight * (1 - decay));
}
/**
* Static method used to find the best index. Width is number of extra bins
* to each side to test.
*/
public static final int getBestIndex(double[] bin, int width) {
double[] score = getBinScores(bin, width);
int bestIndex = (bin.length - 1) / 2; /* TODO: This could be problematic */
for (int i = 0; i < bin.length; ++i)
if (score[i] > score[bestIndex])
bestIndex = i;
return bestIndex;
}
/**
* Gets the scores for each bin in the given stat bin.
*/
protected static final double[] getBinScores(double[] bin, int width) {
double[] scores = new double[bin.length];
for (int i = 0; i < bin.length; ++i) {
double score = 0;
// It is a little complicated in there, but things will
// never go out of bounds
for (int j = -width; j < width + 1; ++j) {
int abs = Math.abs(j) + 1;
if (i + j < 0 || i + j >= bin.length) {
if (i == 0 || i == bin.length - 1) {
score += bin[i - j] / abs;
} else {
int offset = (j < 0) ? -3 : 3;
score += bin[i - j + offset] / abs;
}
} else {
score += bin[i + j] / abs;
}
}
scores[i] = score;
}
return scores;
}
/**
* Converts a bin index to a guessfactor based on total number of bins.
*/
public static final double indexToGF(int index, int bins) {
index = Math.min(Math.max(0, index), bins - 1);
double half = (bins - 1.0) / 2.0;
return (index / half) - 1.0;
}
/**
* Converts a guessfactor to a bin index, based on number of bins. This
* returns a double, incase there is any need to know how much it over hangs
* each bin. Cast to an int for the raw information.
*/
public static final double GFToIndex(double gf, int bins) {
gf = Math.min(Math.max(-1.0, gf), 1.0) + 1.0;
double half = (bins - 1.0) / 2.0;
return gf * half;
}
/**
* Computation of decay rate
*/
public static double computeDecayRate(double halfLife) {
return Math.exp(Math.log(0.5) / halfLife);
}
}
chase.s2.stat.StatBufferSet
package chase.s2.stat;
import java.util.ArrayList;
import java.util.List;
/**
* This class handles multiple stat buffers, as if they were one.
*/
public final class StatBufferSet {
private static final class StatItem {
StatBuffer buffer;
double weight;
}
private List<StatItem> autobin = new ArrayList<StatItem>();
/**
* Add a stat buffer to this buffer set.
*/
public void add(StatBuffer bin, double weight) {
StatItem si = new StatItem();
si.buffer = bin;
si.weight = weight;
autobin.add(si);
}
/**
* Get a stat buffer from this buffer set.
*/
public StatBuffer get(int index) {
return autobin.get(index).buffer;
}
/**
* Remove a statbuffer from this buffer set
*/
public void remove(int index) {
autobin.remove(index);
}
/**
* Returns the number of stat buffers.
*/
public int size() {
return autobin.size();
}
/**
* Gets the single best GF from each StatBuffer.
*/
public double[] getBestGFList(StatData data) {
double[] output = new double[autobin.size()];
int i = 0;
for (StatItem s : autobin) {
output[i++] = s.buffer.getBestGF(data);
}
return output;
}
/**
* Gets a list of all the bins for the raw data.
*/
private double[][] getBinList(StatData data) {
double[][] output = new double[autobin.size()][];
int i = 0;
for (StatItem s : autobin) {
output[i++] = s.buffer.getStatBin(data);
}
return output;
}
/**
* Gets the list of weights.
*/
private double[] getWeightList() {
double[] output = new double[autobin.size()];
int i = 0;
for (StatItem s : autobin) {
output[i++] = s.weight;
}
return output;
}
/**
* Gets the combined score data for the given stat data.
*/
public double[] getCombinedScoreData(StatData sd) {
double[][] data = getBinList(sd);
double[] weights = getWeightList();
return getCombinedScoreData(data, weights);
}
/**
* This combines the data over all the bins in such a way that it can be
* read easily as if it were a single stat bin.
*/
private double[] getCombinedScoreData(double[][] data, double[] weights) {
if (weights.length != data.length)
throw new IllegalArgumentException(
"Data length and weights length must match.");
/* Determine the longest and shortest bin set */
int shortest = Integer.MAX_VALUE;
int longest = Integer.MIN_VALUE;
for (double[] d : data) {
if (d.length > longest)
longest = d.length;
if (d.length < shortest)
shortest = d.length;
}
/* Get each of their scores, and record the largest of each. */
double[][] score = new double[data.length][];
double[] largest = new double[data.length];
for (int i = 0; i < data.length; ++i) {
score[i] = StatBuffer.getBinScores(data[i], StatBuffer.scanWidth);
for (int j = 0; j < score[i].length; ++j)
if (score[i][j] > largest[i])
largest[i] = score[i][j];
}
/* Equalize each of the stat bins */
for (int i = 0; i < data.length; ++i)
for (int j = 0; j < score[i].length; ++j)
score[i][j] /= largest[i];
/* If they are equal, take the easy route */
if (shortest == longest) {
largest = new double[shortest];
for (int i = 0; i < data.length; ++i)
for (int j = 0; j < shortest; ++j)
largest[j] += data[i][j] * weights[i];
return largest;
}
/* Otherwise we have to do things the 'hard' way! */
/* We use the longest and combine the sums from the others, based on gf */
largest = new double[longest];
for (int i = 0; i < data.length; ++i) {
double[] tmpSum = new double[longest];
/* Get the gf for the new length and multiply it by the old weight */
for (int j = 0; j < score[i].length; ++j) {
double index = StatBuffer.GFToIndex(StatBuffer.indexToGF(j,
score[i].length), longest);
StatBuffer.updateBin(tmpSum, index, score[i][j]);
}
/* Add to output buffer */
for (int j = 0; j < longest; ++j) {
largest[j] += tmpSum[j] * weights[i];
}
}
return largest;
}
/**
* Gets the best GF based on weights.
*/
public double getBestGF(StatData data) {
double[] score = getCombinedScoreData(data);
int bestIndex = (score.length - 1) / 2;
for (int i = 0; i < score.length; ++i)
if (score[i] > score[bestIndex])
bestIndex = i;
return StatBuffer.indexToGF(bestIndex, score.length);
}
/**
* Updates this stat buffer handler with the given raw data
*/
public void update(StatData data, double weight) {
for (StatItem s : autobin) {
s.buffer.update(data, weight);
}
}
}
chase.s2.stat.SplitSet
package chase.s2.stat;
import java.util.ArrayDeque;
import java.util.Deque;
/**
* For the really lazy!
*
* @author Chase
*/
public class SplitSet {
public Deque<double[]> split = new ArrayDeque<double[]>();
public Deque<Integer> indexes = new ArrayDeque<Integer>();
public void add(double[] d, int index) {
split.add(d);
indexes.add(index);
}
public double[][] getSplitSet() {
Object[] obj = split.toArray();
double[][] output = new double[obj.length][];
for(int i=0; i<obj.length; ++i) {
output[i] = (double[])obj[i];
}
return output;
}
public int[] getIndexSet() {
Object[] obj = indexes.toArray();
int[] output = new int[obj.length];
for(int i=0; i<obj.length; ++i) {
output[i] = (Integer)obj[i];
}
return output;
}
}
chase.s2.stat.StatData
package chase.s2.stat;
/**
* This holds data.
*
* @author Chase
*/
public class StatData {
public double _data[], _gf, _max;
public boolean range;
public StatData(double[] data, double gf) {
_data = data;
_gf = gf;
range = false;
}
public StatData(double[] data, double min, double max) {
_data = data;
_gf = min;
_max = max;
range = true;
}
}