Mercurial > repos > yufei-luo > s_mart
comparison smart_toolShed/SMART/Java/Python/clusterizeBySlidingWindows.py @ 0:e0f8dcca02ed
Uploaded S-MART tool. A toolbox manages RNA-Seq and ChIP-Seq data.
author | yufei-luo |
---|---|
date | Thu, 17 Jan 2013 10:52:14 -0500 |
parents | |
children |
comparison
equal
deleted
inserted
replaced
-1:000000000000 | 0:e0f8dcca02ed |
---|---|
1 #! /usr/bin/env python | |
2 # | |
3 # Copyright INRA-URGI 2009-2010 | |
4 # | |
5 # This software is governed by the CeCILL license under French law and | |
6 # abiding by the rules of distribution of free software. You can use, | |
7 # modify and/ or redistribute the software under the terms of the CeCILL | |
8 # license as circulated by CEA, CNRS and INRIA at the following URL | |
9 # "http://www.cecill.info". | |
10 # | |
11 # As a counterpart to the access to the source code and rights to copy, | |
12 # modify and redistribute granted by the license, users are provided only | |
13 # with a limited warranty and the software's author, the holder of the | |
14 # economic rights, and the successive licensors have only limited | |
15 # liability. | |
16 # | |
17 # In this respect, the user's attention is drawn to the risks associated | |
18 # with loading, using, modifying and/or developing or reproducing the | |
19 # software by the user in light of its specific status of free software, | |
20 # that may mean that it is complicated to manipulate, and that also | |
21 # therefore means that it is reserved for developers and experienced | |
22 # professionals having in-depth computer knowledge. Users are therefore | |
23 # encouraged to load and test the software's suitability as regards their | |
24 # requirements in conditions enabling the security of their systems and/or | |
25 # data to be ensured and, more generally, to use and operate it in the | |
26 # same conditions as regards security. | |
27 # | |
28 # The fact that you are presently reading this means that you have had | |
29 # knowledge of the CeCILL license and that you accept its terms. | |
30 # | |
31 import re | |
32 from commons.core.writer.WriterChooser import WriterChooser | |
33 """ | |
34 Cluster the data into regions (defined by size and overlap with next region) and keep only highest peaks. | |
35 """ | |
36 | |
37 import os, os.path | |
38 from optparse import OptionParser | |
39 from SMART.Java.Python.structure.Transcript import Transcript | |
40 from SMART.Java.Python.structure.TranscriptContainer import TranscriptContainer | |
41 from SMART.Java.Python.misc.RPlotter import RPlotter | |
42 from SMART.Java.Python.misc.Progress import Progress | |
43 from commons.core.writer.Gff3Writer import Gff3Writer | |
44 | |
45 class ClusterizeBySlidingWindows(object): | |
46 | |
47 def __init__(self, verbosity = 0): | |
48 self.verbosity = verbosity | |
49 self.strands = (0, ) | |
50 self.normalize = False | |
51 self.plot = None | |
52 self.excel = None | |
53 self.outputFileName = '' | |
54 self.defaultValue = None | |
55 | |
56 def __del__(self): | |
57 pass | |
58 | |
59 def setInputFile(self, fileName, format): | |
60 self.parser = TranscriptContainer(fileName, format, self.verbosity) | |
61 | |
62 def setOutputFileName(self, fileName, format="gff", title="S-MART", feature="transcript", featurePart="exon"): | |
63 writerChooser = WriterChooser(self.verbosity) | |
64 writerChooser.findFormat(format) | |
65 self.writer = writerChooser.getWriter(fileName) | |
66 self.writer.setTitle(title) | |
67 self.writer.setFeature(feature) | |
68 self.writer.setFeaturePart(featurePart) | |
69 # self.outputFileName = fileName | |
70 # self.outputFormat = format | |
71 | |
72 def setWindowSize(self, size): | |
73 self.size = size | |
74 | |
75 def setWindowOverlap(self, overlap): | |
76 self.overlap = overlap | |
77 | |
78 def setTag(self, tag): | |
79 self.tag = tag | |
80 | |
81 def setOperation(self, operation): | |
82 self.operation = operation | |
83 | |
84 def setBothStrands(self, bothStrands): | |
85 if bothStrands: | |
86 self.strands = (-1, 1) | |
87 | |
88 def setNormalize(self, normalize): | |
89 self.normalize = normalize | |
90 | |
91 def setPlot(self, plot): | |
92 self.plot = plot | |
93 | |
94 def setExcel(self, excel): | |
95 self.excel = excel | |
96 | |
97 def setOutputTag(self, tag): | |
98 self.outputTagName = tag | |
99 | |
100 def setDefaultValue(self, defaultValue): | |
101 self.defaultValue = defaultValue | |
102 | |
103 def checkOptions(self): | |
104 # if self.operation != None: | |
105 # raise Exception("Trying to combine the values without specifying tag! Aborting...") | |
106 if self.operation != None and self.operation not in ("sum", "avg", "med", "min", "max"): | |
107 raise Exception("Do not understand tag '%s'! Aborting..." % (self.operation)) | |
108 | |
109 def getChromosomeSizes(self): | |
110 self.sizes = {} | |
111 progress = Progress(self.parser.getNbTranscripts(), "Getting sizes in genome", self.verbosity) | |
112 for transcript in self.parser.getIterator(): | |
113 self.sizes[transcript.getChromosome()] = max(transcript.getStart(), self.sizes.get(transcript.getChromosome(), 0)) | |
114 progress.inc() | |
115 progress.done() | |
116 | |
117 def getBinsFromPos(self, pos): | |
118 bin = (pos - 1) / (self.size - self.overlap) | |
119 if bin >= 1 and pos <= bin * (self.size - self.overlap) + self.overlap: | |
120 return (bin - 1, bin) | |
121 return (bin, ) | |
122 | |
123 def getPosFromBin(self, bin): | |
124 return (bin * (self.size - self.overlap) + 1, bin * (self.size - self.overlap) + self.size) | |
125 | |
126 def initializeBins(self): | |
127 self.binsPerStrand = {} | |
128 self.sumsPerStrand = {} | |
129 self.valuesPerStrand = {} | |
130 self.toBePlottedPerStrand = {} | |
131 for strand in self.strands: | |
132 self.binsPerStrand[strand] = {} | |
133 self.sumsPerStrand[strand] = {} | |
134 self.valuesPerStrand[strand] = {} | |
135 self.toBePlottedPerStrand[strand] = {} | |
136 for chromosome in self.sizes: | |
137 binRange = range(self.getBinsFromPos(self.sizes[chromosome])[-1] + 1) | |
138 self.binsPerStrand[strand][chromosome] = dict([[i, 0] for i in binRange]) | |
139 self.sumsPerStrand[strand][chromosome] = dict([[i, 0.0] for i in binRange]) | |
140 self.valuesPerStrand[strand][chromosome] = dict([[i, []] for i in binRange]) | |
141 self.toBePlottedPerStrand[strand][chromosome] = dict([[i, 0] for i in binRange]) | |
142 | |
143 def getNbElements(self, transcript): | |
144 nbOccurrences = 1 if "nbOccurrences" not in transcript.getTagNames() else transcript.getTagValue("nbOccurrences") | |
145 nbElements = 1 if "nbElements" not in transcript.getTagNames() else transcript.getTagValue("nbElements") | |
146 nbOccurrences = float(nbOccurrences) | |
147 nbElements = float(nbElements) | |
148 nbElements /= float(nbOccurrences) | |
149 return nbElements | |
150 | |
151 def setBins(self): | |
152 progress = Progress(self.parser.getNbTranscripts(), "Setting bins", self.verbosity) | |
153 for transcript in self.parser.getIterator(): | |
154 nbElements = self.getNbElements(transcript) | |
155 strand = transcript.getDirection() if len(self.strands) == 2 else 0 | |
156 for bin in self.getBinsFromPos(transcript.getStart()): | |
157 self.binsPerStrand[strand][transcript.getChromosome()][bin] += nbElements | |
158 if self.tag != None: | |
159 if self.tag not in transcript.getTagNames(): | |
160 if self.defaultValue is None: | |
161 raise Exception("Tag %s undefined in transcript %s" % (self.tag, transcript)) | |
162 value = self.defaultValue | |
163 else: | |
164 value = float(transcript.getTagValue(self.tag)) | |
165 self.sumsPerStrand[strand][transcript.getChromosome()][bin] += value | |
166 self.valuesPerStrand[strand][transcript.getChromosome()][bin].append(value) | |
167 progress.inc() | |
168 progress.done() | |
169 | |
170 def aggregateData(self): | |
171 if self.operation == "sum": | |
172 self.computeSumData() | |
173 elif self.operation == "avg": | |
174 self.computeAvgData() | |
175 elif self.operation == "med": | |
176 self.computeMedData() | |
177 elif self.operation == "min": | |
178 self.computeMinData() | |
179 elif self.operation == "max": | |
180 self.computeMaxData() | |
181 elif self.operation == "GCpercent": | |
182 self.computeGCPercent() | |
183 else: | |
184 self.toBePlottedPerStrand = self.binsPerStrand | |
185 | |
186 def computeSumData(self): | |
187 self.toBePlottedPerStrand = self.sumsPerStrand | |
188 | |
189 def computeAvgData(self): | |
190 for strand in self.strands: | |
191 for chromosome in self.binsPerStrand[strand]: | |
192 for bin in self.binsPerStrand[strand][chromosome]: | |
193 if self.binsPerStrand[strand][chromosome][bin] != 0: | |
194 self.toBePlottedPerStrand[strand][chromosome][bin] = float(self.sumsPerStrand[strand][chromosome][bin]) / self.binsPerStrand[strand][chromosome][bin] | |
195 | |
196 def computeMedData(self): | |
197 for strand in self.strands: | |
198 for chromosome in self.binsPerStrand[strand]: | |
199 for bin in self.binsPerStrand[strand][chromosome]: | |
200 if self.valuesPerStrand[strand][chromosome][bin]: | |
201 self.valuesPerStrand[strand][chromosome][bin].sort() | |
202 size = len(self.valuesPerStrand[strand][chromosome][bin]) | |
203 if size % 2 == 1: | |
204 self.toBePlottedPerStrand[strand][chromosome][bin] = self.valuesPerStrand[strand][chromosome][bin][(size - 1) / 2] | |
205 else: | |
206 self.toBePlottedPerStrand[strand][chromosome][bin] = (self.valuesPerStrand[strand][chromosome][bin][size / 2 - 1] + self.valuesPerStrand[strand][chromosome][bin][size / 2]) / 2.0 | |
207 | |
208 def computeMinData(self): | |
209 for strand in self.strands: | |
210 for chromosome in self.binsPerStrand[strand]: | |
211 for bin in self.binsPerStrand[strand][chromosome]: | |
212 if self.valuesPerStrand[strand][chromosome][bin]: | |
213 self.toBePlottedPerStrand[strand][chromosome][bin] = min(self.valuesPerStrand[strand][chromosome][bin]) | |
214 | |
215 def computeMaxData(self): | |
216 for strand in self.strands: | |
217 for chromosome in self.binsPerStrand[strand]: | |
218 for bin in self.binsPerStrand[strand][chromosome]: | |
219 if self.valuesPerStrand[strand][chromosome][bin]: | |
220 self.toBePlottedPerStrand[strand][chromosome][bin] = max(self.valuesPerStrand[strand][chromosome][bin]) | |
221 | |
222 def computeGCPercent(self): | |
223 for strand in self.strands: | |
224 for chromosome in self.binsPerStrand[strand]: | |
225 for bin in self.binsPerStrand[strand][chromosome]: | |
226 if self.valuesPerStrand[strand][chromosome][bin]: | |
227 subSequence = self.valuesPerStrand[strand][chromosome][bin] | |
228 NPercent = 100 * (subSequence.countNt("N") / float(subSequence.getSize())) | |
229 if NPercent >= 50: | |
230 currentGCpercent = "NA" | |
231 else: | |
232 currentGCpercent = subSequence.getGCpercentageInSequenceWithoutCountNInLength() | |
233 | |
234 self.toBePlottedPerStrand[strand][chromosome][bin] = currentGCpercent | |
235 #TODO: see if a map method could be used for the various "compute" methods | |
236 #return currentGCpercent, NPercent | |
237 | |
238 def plotData(self): | |
239 if self.plot != None: | |
240 for strand in self.strands: | |
241 adjunct = "" | |
242 if strand != 0: | |
243 adjunct = "Strand%d" % (strand) | |
244 for chromosome in self.toBePlottedPerStrand[strand]: | |
245 if len(self.toBePlottedPerStrand[strand][chromosome].keys()) > 0: | |
246 plotter = RPlotter(self.plot, self.verbosity) | |
247 plotter.setFill(0) | |
248 plotter.addLine(self.toBePlottedPerStrand[strand][chromosome], chromosome) | |
249 plotter.plot() | |
250 | |
251 def writeExcel(self): | |
252 if self.excel != None: | |
253 excelFile = open(self.excel, "w") | |
254 for strand in self.strands: | |
255 maxBin = max([max(self.toBePlottedPerStrand[strand][chromosome].keys()) for chromosome in self.binsPerStrand[strand]]) | |
256 for bin in range(0, maxBin + 1): | |
257 excelFile.write(",%d-%d" % self.getPosFromBin(bin)) | |
258 excelFile.write("\n") | |
259 for chromosome in self.toBePlottedPerStrand[strand]: | |
260 excelFile.write("%s" % (chromosome)) | |
261 for bin in self.toBePlottedPerStrand[strand][chromosome]: | |
262 excelFile.write(",%f" % (self.toBePlottedPerStrand[strand][chromosome][bin])) | |
263 excelFile.write("\n") | |
264 excelFile.close() | |
265 | |
266 def printRegions(self): | |
267 cpt = 1 | |
268 tagOp = "nb" | |
269 tagName = "Elements" | |
270 outputTagName = "nbElements" | |
271 if self.operation != None: | |
272 tagOp = self.operation.lower() | |
273 if self.tag != None: | |
274 tagName = self.tag.title() | |
275 if self.outputTagName != None: | |
276 outputTagName = self.outputTagName | |
277 | |
278 | |
279 #writer = Gff3Writer(self.outputFileName, self.verbosity) | |
280 | |
281 for strand in self.strands: | |
282 for chromosome in self.toBePlottedPerStrand[strand]: | |
283 for bin in self.toBePlottedPerStrand[strand][chromosome]: | |
284 transcript = Transcript() | |
285 transcript.setName("region%d" % cpt) | |
286 transcript.setChromosome(chromosome) | |
287 transcript.setStart(self.getPosFromBin(bin)[0]) | |
288 transcript.setEnd(self.getPosFromBin(bin)[1]) | |
289 transcript.setDirection(1 if strand == 0 else strand) | |
290 transcript.setTagValue(outputTagName, self.binsPerStrand[strand][chromosome][bin]) | |
291 transcript.setTagValue("%s%s" % (tagOp, tagName), str(self.toBePlottedPerStrand[strand][chromosome][bin])) | |
292 self.writer.addTranscript(transcript) | |
293 cpt += 1 | |
294 self.writer.close() | |
295 | |
296 def run(self): | |
297 self.checkOptions() | |
298 self.getChromosomeSizes() | |
299 self.initializeBins() | |
300 self.setBins() | |
301 self.aggregateData() | |
302 if self.excel: | |
303 self.writeExcel() | |
304 if self.plot: | |
305 self.plotData() | |
306 self.printRegions() | |
307 | |
308 | |
309 if __name__ == "__main__": | |
310 | |
311 # parse command line | |
312 description = "Clusterize by Sliding Windows v1.0.1: Produces a GFF3 file that clusters a list of transcripts using a sliding window. [Category: Sliding Windows]" | |
313 | |
314 parser = OptionParser(description = description) | |
315 parser.add_option("-i", "--input", dest="inputFileName", action="store", type="string", help="input file [compulsory] [format: file in transcript format given by -f]") | |
316 parser.add_option("-f", "--inputFormat", dest="inputFormat", action="store", type="string", help="format of the input file [compulsory] [format: transcript file format]") | |
317 parser.add_option("-o", "--output", dest="outputFileName", action="store", type="string", help="output file [compulsory] [format: output file in transcript format given by -u]") | |
318 parser.add_option("-u", "--outputFormat", dest="outputFormat", action="store", default="gff", type="string", help="format of the output file [format: transcript file format]") | |
319 parser.add_option("-s", "--size", dest="size", action="store", type="int", help="size of the regions [compulsory] [format: int]") | |
320 parser.add_option("-e", "--overlap", dest="overlap", action="store", type="int", help="overlap between two consecutive regions [compulsory] [format: int]") | |
321 parser.add_option("-m", "--normalize", dest="normalize", action="store_true", default=False, help="normalize the number of reads per cluster by the number of mappings per read [format: bool] [default: false]") | |
322 parser.add_option("-g", "--tag", dest="tag", action="store", default=None, type="string", help="use a given tag as input (instead of summing number of features) [format: string]") | |
323 parser.add_option("-r", "--operation", dest="operation", action="store", default=None, type="string", help="combine tag value with given operation [format: choice (sum, avg, med, min, max)]") | |
324 parser.add_option("-d", "--defaultValue",dest="defaultValue", action="store", type="float", help="default value for input tag [format: float]") | |
325 parser.add_option("-w", "--write", dest="writeTag", action="store", default=None, type="string", help="print the result in the given tag (default usually is 'nbElements') [format: string]") | |
326 parser.add_option("-2", "--strands", dest="strands", action="store_true", default=False, help="consider the two strands separately [format: bool] [default: false]") | |
327 parser.add_option("-p", "--plot", dest="plot", action="store", default=None, type="string", help="plot regions to the given file [format: output file in PNG format]") | |
328 parser.add_option("-x", "--excel", dest="excel", action="store", default=None, type="string", help="write an Excel file to the given file [format: output file in Excel format]") | |
329 parser.add_option("-v", "--verbosity", dest="verbosity", action="store", default=1, type="int", help="trace level [format: int] [default: 1]") | |
330 (options, args) = parser.parse_args() | |
331 | |
332 cbsw = ClusterizeBySlidingWindows(options.verbosity) | |
333 cbsw.setInputFile(options.inputFileName, options.inputFormat) | |
334 cbsw.setOutputFileName(options.outputFileName, options.outputFormat) | |
335 cbsw.setWindowSize(options.size) | |
336 cbsw.setWindowOverlap(options.overlap) | |
337 cbsw.setTag(options.tag) | |
338 cbsw.setDefaultValue(options.defaultValue) | |
339 cbsw.setOperation(options.operation) | |
340 cbsw.setOutputTag(options.writeTag) | |
341 cbsw.setBothStrands(options.strands) | |
342 cbsw.setPlot(options.plot) | |
343 cbsw.setExcel(options.excel) | |
344 cbsw.run() |