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|
# Copyright (C) University of Tennessee Health Science Center, Memphis, TN.
#
# This program is free software: you can redistribute it and/or modify it
# under the terms of the GNU Affero General Public License
# as published by the Free Software Foundation, either version 3 of the
# License, or (at your option) any later version.
#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
# See the GNU Affero General Public License for more details.
#
# This program is available from Source Forge: at GeneNetwork Project
# (sourceforge.net/projects/genenetwork/).
#
# Contact Drs. Robert W. Williams and Xiaodong Zhou (2010)
# at rwilliams@uthsc.edu and xzhou15@uthsc.edu
#
# This module is used by GeneNetwork project (www.genenetwork.org)
#
# Created by GeneNetwork Core Team 2010/08/10
#
# Last updated by GeneNetwork Core Team 2010/10/20
import time
import string
import math
from math import *
import piddle as pid
import sys,os
import httplib, urllib
from htmlgen import HTMLgen2 as HT
from utility import Plot
from intervalAnalyst import GeneUtil
from base.webqtlTrait import webqtlTrait
from base.templatePage import templatePage
from utility import webqtlUtil
from base import webqtlConfig
from dbFunction import webqtlDatabaseFunction
from base.GeneralObject import GeneralObject
import reaper
import cPickle
from utility.THCell import THCell
from utility.TDCell import TDCell
class MarkerRegressionPage(templatePage):
def __init__(self, fd):
templatePage.__init__(self, fd)
if not self.openMysql():
return
self.initializeParameters(fd)
filename= webqtlUtil.genRandStr("Itvl_")
ChrList,ChrNameOrderIdDict,ChrOrderIdNameDict,ChrLengthMbList= self.getChrNameOrderIdLength(RISet=fd.RISet)
if self.mappingMethodId == '4': # For PLINK
traitInfoList = string.split(string.strip(fd.identification),':')
probesetName = string.strip(traitInfoList[-1])
plinkOutputFileName= webqtlUtil.genRandStr("%s_%s_"%(fd.RISet,probesetName))
# get related values from fd.allTraitData; the format of 'allTraitValueDict'is {strainName1: value=-0.2...}
fd.readData()
allTraitValueDict = fd.allTraitData
#automatically generate pheno txt file for PLINK
self.genPhenoTxtFileForPlink(phenoFileName=plinkOutputFileName,RISetName=fd.RISet,probesetName=probesetName, valueDict=allTraitValueDict)
# os.system full path is required for input and output files; specify missing value is -9999
plink_command = '%splink/plink --noweb --ped %splink/%s.ped --no-fid --no-parents --no-sex --no-pheno --map %splink/%s.map --pheno %s/%s.txt --pheno-name %s --missing-phenotype -9999 --out %s%s --assoc ' % (webqtlConfig.GENODIR, webqtlConfig.GENODIR, fd.RISet, webqtlConfig.GENODIR, fd.RISet, webqtlConfig.TMPDIR, plinkOutputFileName, probesetName, webqtlConfig.TMPDIR, plinkOutputFileName)
os.system(plink_command)
if fd.identification:
heading2 = HT.Paragraph('Trait ID: %s' % fd.identification)
heading2.__setattr__("class","subtitle")
self.dict['title'] = '%s: Genome Association' % fd.identification
else:
heading2 = ""
self.dict['title'] = 'Genome Association'
if fd.traitInfo:
symbol,chromosome,MB = string.split(fd.traitInfo,'\t')
heading3 = HT.Paragraph('[ ',HT.Strong(HT.Italic('%s' % symbol,id="green")),' on Chr %s @ %s Mb ]' % (chromosome,MB))
else:
heading3 = ""
heading = HT.Paragraph('Trait Data Entered for %s Set' % fd.RISet)
heading.__setattr__("class","title")
# header info part:Trait Data Entered for HLC Set & Trait ID:
headerdiv = HT.TR(HT.TD(heading, heading2,heading3, width='45%',valign='top', align='left', bgColor='#eeeeee'))
self.ChrList=ChrList # get chr name from '1' to 'X'
self.ChrLengthMbList = ChrLengthMbList
# build plink result dict based on chr, key is chr name, value is in list type including Snpname, bp and pvalue info
plinkResultDict={}
count,minPvalue,plinkResultDict =self.getPlinkResultDict(outputFileName=plinkOutputFileName,thresholdPvalue=self.pValue,ChrOrderIdNameDict=ChrOrderIdNameDict)
# if can not find results which are matched with assigned p-value, system info will show up
if count >0:
#for genome association report table
reportTable=""
# sortable table object
resultstable,tblobj,bottomInfo = self.GenReportForPLINK(ChrNameOrderIdDict=ChrNameOrderIdDict, RISet=fd.RISet,plinkResultDict=plinkResultDict,thresholdPvalue=self.pValue,chrList=self.ChrList)
# creat object for result table for sort function
objfile = open('%s.obj' % (webqtlConfig.TMPDIR+filename), 'wb')
cPickle.dump(tblobj, objfile)
objfile.close()
sortby = ("Index", "up")
reportTable =HT.Div(webqtlUtil.genTableObj(tblobj=tblobj, file=filename, sortby=sortby, tableID = "sortable", addIndex = "0"), Id="sortable")
descriptionTable = HT.TableLite(border=0, cellpadding=0, cellspacing=0)
descriptionTable.append(HT.TR(HT.TD(reportTable, colspan=3)))
descriptionTable.append(HT.TR(HT.TD(HT.BR(),HT.BR())))
descriptionTable.append(bottomInfo)
# get each chr's length
self.ChrLengthMbList = map(lambda x: x/1000000.0, self.ChrLengthMbList) # change unit from bp to mb
self.ChrLengthMbSum = reduce(lambda x, y:x+y, self.ChrLengthMbList, 0.0)# get total length of all chrs
if self.ChrLengthMbList:
self.GraphInterval = self.ChrLengthMbSum/(len(self.ChrLengthMbList)*12) #Empirical Mb interval
else:
self.GraphInterval = 1
# for human data, there's no CM value
self.ChrLengthCMList = []
self.ChrLengthCMSum = 0
# begin: common part with human data
intCanvas = pid.PILCanvas(size=(self.graphWidth,self.graphHeight))
gifmap = self.plotIntMappingForPLINK(fd, intCanvas, startMb = self.startMb, endMb = self.endMb, plinkResultDict=plinkResultDict)
intCanvas.save(os.path.join(webqtlConfig.GENERATED_IMAGE_DIR, filename), format='png')
intImg=HT.Image('/image/'+filename+'.png', border=0, usemap='#WebQTLImageMap')
TD_LR = HT.TR(HT.TD(HT.Blockquote(gifmap,intImg, HT.P()), bgColor='#eeeeee', height = 200))
self.dict['body'] = str(headerdiv)+str(TD_LR)+str(resultstable)+str(HT.TR(HT.TD(descriptionTable)))
else:
heading = "Genome Association"
detail = ['There is no association with marker that meets this criteria. Please provide a less stringend threshold. The minimun p-value is %s.'%minPvalue]
self.error(heading=heading,detail=detail)
return
elif self.mappingMethodId == '1': # QTLreaper result
if not fd.genotype:
fd.readData()
fd.parentsf14regression = fd.formdata.getvalue('parentsf14regression')
weightedRegression = fd.formdata.getvalue('applyVarianceSE')
if fd.parentsf14regression and fd.genotype_2:
_genotype = fd.genotype_2
else:
_genotype = fd.genotype_1
_strains, _vals, _vars, N = fd.informativeStrains(_genotype.prgy, weightedRegression)
if fd.identification:
heading2 = HT.Paragraph('Trait ID: %s' % fd.identification)
heading2.__setattr__("class","subtitle")
self.dict['title'] = '%s: Genome Association' % fd.identification
else:
heading2 = ""
self.dict['title'] = 'Genome Association'
if fd.traitInfo:
symbol,chromosome,MB = string.split(fd.traitInfo,'\t')
heading3 = HT.Paragraph('[ ',HT.Strong(HT.Italic('%s' % symbol,id="green")),' on Chr %s @ %s Mb ]' % (chromosome,MB))
else:
heading3 = ""
if N < webqtlConfig.KMININFORMATIVE:
heading = "Genome Association"
detail = ['Fewer than %d strain data were entered for %s data set. No mapping attempted.' % (webqtlConfig.KMININFORMATIVE, fd.RISet)]
self.error(heading=heading,detail=detail)
return
else:
heading = HT.Paragraph('Trait Data Entered for %s Set' % fd.RISet)
heading.__setattr__("class","title")
datadiv = HT.TD(heading, heading2,heading3, width='45%',valign='top', align='left', bgColor='#eeeeee')
resultstable,tblobj,bottomInfo = self.GenReport(ChrNameOrderIdDict,fd, _genotype, _strains, _vals, _vars)
#resultstable = self.GenReport(fd, _genotype, _strains, _vals, _vars)
# creat object for result table for sort function
objfile = open('%s.obj' % (webqtlConfig.TMPDIR+filename), 'wb')
cPickle.dump(tblobj, objfile)
objfile.close()
sortby = ("Index", "up")
reportTable =HT.Div(webqtlUtil.genTableObj(tblobj=tblobj, file=filename, sortby=sortby, tableID = "sortable", addIndex = "0"), Id="sortable")
descriptionTable = HT.TableLite(border=0, cellpadding=0, cellspacing=0)
descriptionTable.append(HT.TR(HT.TD(reportTable, colspan=3)))
descriptionTable.append(HT.TR(HT.TD(HT.BR(),HT.BR())))
descriptionTable.append(bottomInfo)
self.traitList=_vals
##########################plot#######################
################################################################
# Generate Chr list and Retrieve Length Information
################################################################
self.genotype= _genotype
self.ChrList = [("All", -1)]
for i, indChr in enumerate(self.genotype):
self.ChrList.append((indChr.name, i))
self.cursor.execute("""
Select
Length from Chr_Length, InbredSet
where
Chr_Length.SpeciesId = InbredSet.SpeciesId AND
InbredSet.Name = '%s' AND
Chr_Length.Name in (%s)
Order by
OrderId
""" % (fd.RISet, string.join(map(lambda X: "'%s'" % X[0], self.ChrList[1:]), ", ")))
self.ChrLengthMbList = self.cursor.fetchall()
self.ChrLengthMbList = map(lambda x: x[0]/1000000.0, self.ChrLengthMbList)
self.ChrLengthMbSum = reduce(lambda x, y:x+y, self.ChrLengthMbList, 0.0)
if self.ChrLengthMbList:
self.MbGraphInterval = self.ChrLengthMbSum/(len(self.ChrLengthMbList)*12) #Empirical Mb interval
else:
self.MbGraphInterval = 1
self.ChrLengthCMList = []
for i, _chr in enumerate(self.genotype):
self.ChrLengthCMList.append(_chr[-1].cM - _chr[0].cM)
self.ChrLengthCMSum = reduce(lambda x, y:x+y, self.ChrLengthCMList, 0.0)# used for calculate plot scale
self.GraphInterval = self.MbGraphInterval #Mb
# begin: common part with human data
intCanvas = pid.PILCanvas(size=(self.graphWidth,self.graphHeight))
gifmap = self.plotIntMapping(fd, intCanvas, startMb = self.startMb, endMb = self.endMb, showLocusForm= "")
filename= webqtlUtil.genRandStr("Itvl_")
intCanvas.save(os.path.join(webqtlConfig.GENERATED_IMAGE_DIR, filename), format='png')
intImg=HT.Image('/image/'+filename+'.png', border=0, usemap='#WebQTLImageMap')
################################################################
# footnote goes here
################################################################
btminfo = HT.Paragraph(Id="smallsize") #Small('More information about this graph is available here.')
if (self.additiveChecked):
btminfo.append(HT.BR(), 'A positive additive coefficient (', HT.Font('green', color='green'), ' line) indicates that %s alleles increase trait values. In contrast, a negative additive coefficient (' % fd.ppolar, HT.Font('red', color='red'), ' line) indicates that %s alleles increase trait values.' % fd.mpolar)
TD_LR = HT.TR(HT.TD(HT.Blockquote(gifmap,intImg, HT.P()), bgColor='#eeeeee', height = 200))
self.dict['body'] = str(datadiv)+str(TD_LR)+str(resultstable)+str(HT.TR(HT.TD(descriptionTable)))
# end: common part with human data
else:
pass
# add by NL 10-2-2011
def initializeParameters(self, fd):
"""
Initializes all of the MarkerRegressionPage class parameters,
acquiring most values from the formdata (fd)
"""
###################################
# manhattam plot parameters
###################################
self.graphHeight = 600
self.graphWidth = 1280
self.plotScale = 'physic'
self.selectedChr = -1
self.GRAPH_BACK_DARK_COLOR = pid.HexColor(0xF1F1F9)
self.GRAPH_BACK_LIGHT_COLOR = pid.HexColor(0xFBFBFF)
self.LRS_COLOR = pid.HexColor(0x0000FF)
self.LRS_LOD ='LRS'
self.lrsMax = float(fd.formdata.getvalue('lrsMax', 0))
self.startMb = fd.formdata.getvalue('startMb', "-1")
self.endMb = fd.formdata.getvalue('endMb', "-1")
self.mappingMethodId = fd.formdata.getvalue('mappingMethodId', "0")
self.permChecked=True
self.multipleInterval=False
self.SIGNIFICANT_WIDTH = 5
self.SUGGESTIVE_WIDTH = 5
self.SIGNIFICANT_COLOR = pid.HexColor(0xEBC7C7)
self.SUGGESTIVE_COLOR = pid.gainsboro
self.colorCollection = [self.LRS_COLOR]
self.additiveChecked= True
self.ADDITIVE_COLOR_POSITIVE = pid.green
self.legendChecked =False
self.pValue=float(fd.formdata.getvalue('pValue',-1))
# allow user to input p-value greater than 1,
# in this case, the value will be treated as -lgP value. so the input value needs to be transferred to power of 10 format
if self.pValue >1:
self.pValue =10**-(self.pValue)
try:
self.startMb = float(self.startMb)
self.endMb = float(self.endMb)
if self.startMb > self.endMb:
temp = self.startMb
self.startMb = self.endMb
self.endMb = temp
#minimal distance 10bp
if self.endMb - self.startMb < 0.00001:
self.endMb = self.startMb + 0.00001
except:
self.startMb = self.endMb = -1
def GenReportForPLINK(self, ChrNameOrderIdDict={},RISet='',plinkResultDict= {},thresholdPvalue=-1,chrList=[]):
'Create an HTML division which reports any loci which are significantly associated with the submitted trait data.'
#########################################
# Genome Association report
#########################################
locusFormName = webqtlUtil.genRandStr("fm_")
locusForm = HT.Form(cgi = os.path.join(webqtlConfig.CGIDIR, webqtlConfig.SCRIPTFILE), \
enctype='multipart/form-data', name=locusFormName, submit=HT.Input(type='hidden'))
hddn = {'FormID':'showDatabase','ProbeSetID':'_','database':RISet+"Geno",'CellID':'_', \
'RISet':RISet, 'incparentsf1':'on'}
for key in hddn.keys():
locusForm.append(HT.Input(name=key, value=hddn[key], type='hidden'))
regressionHeading = HT.Paragraph('Genome Association Report')
regressionHeading.__setattr__("class","title")
filename= webqtlUtil.genRandStr("GenomeAsscociation_")
fpText = open('%s.txt' % (webqtlConfig.TMPDIR+filename), 'wb')
fpText.write('The loci meet the criteria of P-Value <= %3.6f.\n'%thresholdPvalue)
pValueInfo =HT.Paragraph('The loci meet the criteria of P-Value <= %3.6f.\n'%thresholdPvalue)
textUrl = HT.Href(text = 'Download', url= '/tmp/'+filename+'.txt', target = "_blank", Class='fs12 fwn')
bottomInfo = HT.TR(HT.TD(HT.Paragraph(textUrl, ' result in tab-delimited text format.', HT.BR(), HT.BR(),Class="fs12 fwn"), colspan=3))
tblobj={} # build dict for genTableObj function; keys include header and body
tblobj_header = [] # value of key 'header'
tblobj_body=[] # value of key 'body'
reportHeaderRow=[] # header row list for tblobj_header (html part)
headerList=['Index','SNP Name','Chr','Mb','-log(P)']
headerStyle="fs14 fwb ffl b1 cw cbrb" # style of the header
cellColorStyle = "fs13 b1 fwn c222" # style of the cells
if headerList:
for ncol, item in enumerate(headerList):
reportHeaderRow.append(THCell(HT.TD(item, Class=headerStyle, valign='bottom',nowrap='ON'),text=item, idx=ncol))
#download file for table headers' names
fpText.write('SNP_Name\tChromosome\tMb\t-log(P)\n')
tblobj_header.append(reportHeaderRow)
tblobj['header']=tblobj_header
index=1
for chr in chrList:
if plinkResultDict.has_key(chr):
if chr in ChrNameOrderIdDict.keys():
chrOrderId =ChrNameOrderIdDict[chr]
else:
chrOrderId=chr
valueList=plinkResultDict[chr]
for value in valueList:
reportBodyRow=[] # row list for tblobj_body (html part)
snpName=value[0]
bp=value[1]
mb=int(bp)/1000000.0
try:
pValue =float(value[2])
except:
pValue =1
formattedPvalue = -math.log10(pValue)
formattedPvalue = webqtlUtil.SciFloat(formattedPvalue)
dbSnprs=snpName.replace('rs','')
SnpHref = HT.Href(text=snpName, url="http://www.ncbi.nlm.nih.gov/projects/SNP/snp_ref.cgi?rs=%s"%dbSnprs, target="_blank")
selectCheck=HT.Input(type="checkbox", Class="checkbox", name="index",value=index, onClick="highlight(this)")
reportBodyRow.append(TDCell(HT.TD(str(index),selectCheck, align='right',Class=cellColorStyle,nowrap='ON'),str(index),index))
reportBodyRow.append(TDCell(HT.TD(SnpHref, Class=cellColorStyle,nowrap='ON'),snpName, snpName))
reportBodyRow.append(TDCell(HT.TD(chr, Class=cellColorStyle, align="center",nowrap='ON'),chr, chrOrderId))
reportBodyRow.append(TDCell(HT.TD('%3.6f'%mb, Class=cellColorStyle, align="center",nowrap='ON'),mb, mb))
reportBodyRow.append(TDCell(HT.TD(formattedPvalue, Class=cellColorStyle, align="center",nowrap='ON'),formattedPvalue, float(formattedPvalue)))
fpText.write('%s\t%s\t%3.6f\t%s\n' % (snpName, str(chr), mb, formattedPvalue))
index+=1
tblobj_body.append(reportBodyRow)
tblobj['body']=tblobj_body
rv=HT.TR(HT.TD(regressionHeading,pValueInfo, locusForm, HT.P(), width='55%',valign='top', align='left',bgColor='#eeeeee'))
return rv, tblobj,bottomInfo
def GenReport(self, ChrNameOrderIdDict,fd, _genotype, _strains, _vals, _vars= []):
'Create an HTML division which reports any loci which are significantly associated with the submitted trait data.'
#calculate QTL for each trait
self.qtlresults = []
if webqtlUtil.ListNotNull(_vars):
qtlresults = _genotype.regression(strains = _strains, trait = _vals, variance = _vars)
LRSArray = _genotype.permutation(strains = _strains, trait = _vals, variance = _vars, nperm=fd.nperm)
else:
qtlresults = _genotype.regression(strains = _strains, trait = _vals)
LRSArray = _genotype.permutation(strains = _strains, trait = _vals,nperm=fd.nperm)
self.qtlresults.append(qtlresults)
filename= webqtlUtil.genRandStr("GenomeAsscociation_")
# set suggestive, significant and highly significant LRS
if fd.suggestive == None:
fd.suggestive = LRSArray[int(fd.nperm*0.37-1)]
else:
fd.suggestive = float(fd.suggestive)
if fd.significance == None:
fd.significance = LRSArray[int(fd.nperm*0.95-1)]
else:
fd.significance = float(fd.significance)
self.significance =fd.significance
self.suggestive = fd.suggestive
self.highlysignificant = LRSArray[int(fd.nperm*0.99-1)]
_dispAllLRS = 0
if fd.formdata.getvalue('displayAllLRS'):
_dispAllLRS = 1
qtlresults2 = []
if _dispAllLRS:
filtered = qtlresults[:]
else:
filtered = filter(lambda x, y=fd.suggestive: x.lrs > y, qtlresults)
if len(filtered) == 0:
qtlresults2 = qtlresults[:]
qtlresults2.sort()
filtered = qtlresults2[-10:]
#########################################
# Permutation Graph
#########################################
myCanvas = pid.PILCanvas(size=(400,300))
#plotBar(myCanvas,10,10,390,290,LRSArray,XLabel='LRS',YLabel='Frequency',title=' Histogram of Permutation Test',identification=fd.identification)
Plot.plotBar(myCanvas, LRSArray,XLabel='LRS',YLabel='Frequency',title=' Histogram of Permutation Test')
filename= webqtlUtil.genRandStr("Reg_")
myCanvas.save(webqtlConfig.GENERATED_IMAGE_DIR+filename, format='gif')
img=HT.Image('/image/'+filename+'.gif',border=0,alt='Histogram of Permutation Test')
if fd.suggestive == None:
fd.suggestive = LRSArray[int(fd.nperm*0.37-1)]
else:
fd.suggestive = float(fd.suggestive)
if fd.significance == None:
fd.significance = LRSArray[int(fd.nperm*0.95-1)]
else:
fd.significance = float(fd.significance)
permutationHeading = HT.Paragraph('Histogram of Permutation Test')
permutationHeading.__setattr__("class","title")
permutation = HT.TableLite()
permutation.append(HT.TR(HT.TD(img)))
#########################################
# Genome Association report
#########################################
locusFormName = webqtlUtil.genRandStr("fm_")
locusForm = HT.Form(cgi = os.path.join(webqtlConfig.CGIDIR, webqtlConfig.SCRIPTFILE), \
enctype='multipart/form-data', name=locusFormName, submit=HT.Input(type='hidden'))
hddn = {'FormID':'showDatabase','ProbeSetID':'_','database':fd.RISet+"Geno",'CellID':'_', \
'RISet':fd.RISet, 'incparentsf1':'on'}
for key in hddn.keys():
locusForm.append(HT.Input(name=key, value=hddn[key], type='hidden'))
regressionHeading = HT.Paragraph('Genome Association Report')
regressionHeading.__setattr__("class","title")
# report is the info part above report table
if qtlresults2 != []:
report = HT.Blockquote(HT.Font('No association ',color="#FF0000"),HT.Font('with a likelihood ratio statistic greater than %3.1f was found. Here are the top 10 LRSs.' % fd.suggestive,color="#000000"))
else:
report = HT.Blockquote('The following loci in the %s data set have associations with the above trait data.\n' % fd.RISet, HT.P())
report.__setattr__("class","normalsize")
fpText = open('%s.txt' % (webqtlConfig.TMPDIR+filename), 'wb')
fpText.write('Suggestive LRS =%3.2f\n'%self.suggestive)
fpText.write('Significant LRS =%3.2f\n'%self.significance)
fpText.write('Highly Significant LRS =%3.2f\n'%self.highlysignificant)
LRSInfo =HT.Paragraph(' Suggestive LRS =%3.2f\n'%fd.suggestive, HT.BR(), ' Significant LRS =%3.2f\n'%fd.significance,HT.BR(),' Highly Significant LRS =%3.2f\n' % self.highlysignificant)
textUrl = HT.Href(text = 'Download', url= '/tmp/'+filename+'.txt', target = "_blank", Class='fs12 fwn')
bottomInfo = HT.TR(HT.TD(HT.Paragraph(textUrl, ' result in tab-delimited text format.', HT.BR(), HT.BR(),'LRS values marked with',HT.Font(' * ',color="red"), 'are greater than the significance threshold (specified by you or by permutation test). ' , HT.BR(), HT.BR(), HT.Strong('Additive Effect'), ' is half the difference in the mean phenotype of all cases that are homozygous for one parental allel at this marker minus the mean of all cases that are homozygous for the other parental allele at this marker. ','In the case of %s strains, for example,' % fd.RISet,' A positive additive effect indicates that %s alleles increase trait values. Negative additive effect indicates that %s alleles increase trait values.'% (fd.ppolar,fd.mpolar),Class="fs12 fwn")))
tblobj={} # build dict for genTableObj function; keys include header and body
tblobj_header = [] # value of key 'header'
tblobj_body=[] # value of key 'body'
reportHeaderRow=[] # header row list for tblobj_header (html part)
headerStyle="fs14 fwb ffl b1 cw cbrb" # style of the header
cellColorStyle = "fs13 b1 fwn c222" # style of the cells
headerList=['Index','LRS','Chr','Mb','Locus','Additive Effect']
for ncol, item in enumerate(headerList):
reportHeaderRow.append(THCell(HT.TD(item, Class=headerStyle, valign='bottom',nowrap='ON'),text=item, idx=ncol))
if fd.genotype.type == 'intercross':
ncol =len(headerList)
reportHeaderRow.append(THCell(HT.TD('Dominance Effect', Class=headerStyle, valign='bottom',nowrap='ON'),text='Dominance Effect', idx=ncol))
#download file for table headers' names
fpText.write('LRS\tChromosome\tMb\tLocus\tAdditive Effect\tDominance Effect\n')
index=1
for ii in filtered:
#add by NL 06-20-2011: set LRS to 460 when LRS is infinite,
if ii.lrs==float('inf') or ii.lrs>webqtlConfig.MAXLRS:
LRS=webqtlConfig.MAXLRS #maximum LRS value
else:
LRS=ii.lrs
if LRS > fd.significance:
lrs = HT.TD(HT.Font('%3.3f*' % LRS, color='#FF0000'),Class=cellColorStyle)
else:
lrs = HT.TD('%3.3f' % LRS,Class=cellColorStyle)
if ii.locus.chr in ChrNameOrderIdDict.keys():
chrOrderId =ChrNameOrderIdDict[ii.locus.chr]
else:
chrOrderId=ii.locus.chr
reportBodyRow=[] # row list for tblobj_body (html part)
selectCheck=HT.Input(type="checkbox", Class="checkbox", name="index",value=index, onClick="highlight(this)")
reportBodyRow.append(TDCell(HT.TD(str(index),selectCheck, align='right',Class=cellColorStyle,nowrap='ON'),str(index),index))
reportBodyRow.append(TDCell(lrs,LRS, LRS))
reportBodyRow.append(TDCell(HT.TD(ii.locus.chr, Class=cellColorStyle, align="center",nowrap='ON'),ii.locus.chr, chrOrderId))
reportBodyRow.append(TDCell(HT.TD('%3.6f'%ii.locus.Mb, Class=cellColorStyle, align="center",nowrap='ON'),ii.locus.Mb, ii.locus.Mb))
reportBodyRow.append(TDCell(HT.TD(HT.Href(text=ii.locus.name, url = "javascript:showTrait('%s','%s');" % (locusFormName, ii.locus.name), Class='normalsize'), Class=cellColorStyle, align="center",nowrap='ON'),ii.locus.name, ii.locus.name))
reportBodyRow.append(TDCell(HT.TD('%3.3f' % ii.additive, Class=cellColorStyle, align="center",nowrap='ON'),ii.additive, ii.additive))
reportBodyRow.append(TDCell(HT.TD('%3.3f' % ii.dominance, Class=cellColorStyle, align="center",nowrap='ON'),ii.dominance, ii.dominance))
fpText.write('%2.3f\t%s\t%3.6f\t%s\t%2.3f\t%2.3f\n' % (LRS, ii.locus.chr, ii.locus.Mb, ii.locus.name, ii.additive, ii.dominance))
index+=1
tblobj_body.append(reportBodyRow)
else:
#download file for table headers' names
fpText.write('LRS\tChromosome\tMb\tLocus\tAdditive Effect\n')
index=1
for ii in filtered:
#add by NL 06-20-2011: set LRS to 460 when LRS is infinite,
if ii.lrs==float('inf') or ii.lrs>webqtlConfig.MAXLRS:
LRS=webqtlConfig.MAXLRS #maximum LRS value
else:
LRS=ii.lrs
if LRS > fd.significance:
lrs = HT.TD(HT.Font('%3.3f*' % LRS, color='#FF0000'),Class=cellColorStyle)
else:
lrs = HT.TD('%3.3f' % LRS,Class=cellColorStyle)
if ii.locus.chr in ChrNameOrderIdDict.keys():
chrOrderId =ChrNameOrderIdDict[ii.locus.chr]
else:
chrOrderId=ii.locus.chr
reportBodyRow=[] # row list for tblobj_body (html part)
selectCheck=HT.Input(type="checkbox", Class="checkbox", name="index",value=index, onClick="highlight(this)")
reportBodyRow.append(TDCell(HT.TD(str(index),selectCheck, align='right',Class=cellColorStyle,nowrap='ON'),str(index),index))
reportBodyRow.append(TDCell(lrs,LRS, LRS))
reportBodyRow.append(TDCell(HT.TD(ii.locus.chr, Class=cellColorStyle, align="center",nowrap='ON'),ii.locus.chr, chrOrderId))
reportBodyRow.append(TDCell(HT.TD('%3.6f'%ii.locus.Mb, Class=cellColorStyle, align="center",nowrap='ON'),ii.locus.Mb, ii.locus.Mb))
reportBodyRow.append(TDCell(HT.TD(HT.Href(text=ii.locus.name, url = "javascript:showTrait('%s','%s');" % (locusFormName, ii.locus.name), Class='normalsize'), Class=cellColorStyle, align="center",nowrap='ON'),ii.locus.name, ii.locus.name))
reportBodyRow.append(TDCell(HT.TD('%3.3f' % ii.additive, Class=cellColorStyle, align="center",nowrap='ON'),ii.additive, ii.additive))
fpText.write('%2.3f\t%s\t%3.6f\t%s\t%2.3f\n' % (LRS, ii.locus.chr, ii.locus.Mb, ii.locus.name, ii.additive))
index+=1
tblobj_body.append(reportBodyRow)
tblobj_header.append(reportHeaderRow)
tblobj['header']=tblobj_header
tblobj['body']=tblobj_body
rv=HT.TD(regressionHeading,LRSInfo,report, locusForm, HT.P(),width='55%',valign='top', align='left', bgColor='#eeeeee')
if fd.genotype.type == 'intercross':
bottomInfo.append(HT.BR(), HT.BR(), HT.Strong('Dominance Effect'),' is the difference between the mean trait value of cases heterozygous at a marker and the average mean for the two groups homozygous at this marker: e.g., BD - (BB+DD)/2]. A positive dominance effect indicates that the average phenotype of BD heterozygotes exceeds the mean of BB and DD homozygotes. No dominance deviation can be computed for a set of recombinant inbred strains or for a backcross.')
return rv,tblobj,bottomInfo
return rv,tblobj,bottomInfo
def plotIntMappingForPLINK(self, fd, canvas, offset= (80, 120, 20, 80), zoom = 1, startMb = None, endMb = None, showLocusForm = "",plinkResultDict={}):
#calculating margins
xLeftOffset, xRightOffset, yTopOffset, yBottomOffset = offset
fontZoom = zoom
if zoom == 2:
fontZoom = 1.5
xLeftOffset = int(xLeftOffset*fontZoom)
xRightOffset = int(xRightOffset*fontZoom)
yBottomOffset = int(yBottomOffset*fontZoom)
cWidth = canvas.size[0]
cHeight = canvas.size[1]
plotWidth = cWidth - xLeftOffset - xRightOffset
plotHeight = cHeight - yTopOffset - yBottomOffset
startPixelX = xLeftOffset
endPixelX = (xLeftOffset + plotWidth)
#Drawing Area Height
drawAreaHeight = plotHeight
if self.plotScale == 'physic' and self.selectedChr > -1: # for single chr
drawAreaHeight -= self.ENSEMBL_BAND_HEIGHT + self.UCSC_BAND_HEIGHT+ self.WEBQTL_BAND_HEIGHT + 3*self.BAND_SPACING+ 10*zoom
if self.geneChecked:
drawAreaHeight -= self.NUM_GENE_ROWS*self.EACH_GENE_HEIGHT + 3*self.BAND_SPACING + 10*zoom
else:
if self.selectedChr > -1:
drawAreaHeight -= 20
else:# for all chrs
drawAreaHeight -= 30
#Image map
gifmap = HT.Map(name='WebQTLImageMap')
newoffset = (xLeftOffset, xRightOffset, yTopOffset, yBottomOffset)
# Draw the alternating-color background first and get plotXScale
plotXScale = self.drawGraphBackgroundForPLINK(canvas, gifmap, offset=newoffset, zoom= zoom, startMb=startMb, endMb = endMb,plinkResultDict=plinkResultDict)
# Draw X axis
self.drawXAxisForPLINK(fd, canvas, drawAreaHeight, gifmap, plotXScale, showLocusForm, offset=newoffset, zoom= zoom, startMb=startMb, endMb = endMb)
# Draw manhattam plot
self.drawManhattanPlotForPLINK(canvas, drawAreaHeight, gifmap, plotXScale, offset=newoffset, zoom= zoom, startMb=startMb, endMb = endMb,plinkResultDict=plinkResultDict,thresholdPvalue=self.pValue)
return gifmap
def plotIntMapping(self, fd, canvas, offset= (80, 120, 20, 80), zoom = 1, startMb = None, endMb = None, showLocusForm = ""):
#calculating margins
xLeftOffset, xRightOffset, yTopOffset, yBottomOffset = offset
fontZoom = zoom
if zoom == 2:
fontZoom = 1.5
xLeftOffset = int(xLeftOffset*fontZoom)
xRightOffset = int(xRightOffset*fontZoom)
yBottomOffset = int(yBottomOffset*fontZoom)
cWidth = canvas.size[0]
cHeight = canvas.size[1]
plotWidth = cWidth - xLeftOffset - xRightOffset
plotHeight = cHeight - yTopOffset - yBottomOffset
startPixelX = xLeftOffset
endPixelX = (xLeftOffset + plotWidth)
#Drawing Area Height
drawAreaHeight = plotHeight
if self.plotScale == 'physic' and self.selectedChr > -1: # for single chr
drawAreaHeight -= self.ENSEMBL_BAND_HEIGHT + self.UCSC_BAND_HEIGHT+ self.WEBQTL_BAND_HEIGHT + 3*self.BAND_SPACING+ 10*zoom
if self.geneChecked:
drawAreaHeight -= self.NUM_GENE_ROWS*self.EACH_GENE_HEIGHT + 3*self.BAND_SPACING + 10*zoom
else:# for all chrs
if self.selectedChr > -1:
drawAreaHeight -= 20
else:
drawAreaHeight -= 30
#Image map
gifmap = HT.Map(name='WebQTLImageMap')
newoffset = (xLeftOffset, xRightOffset, yTopOffset, yBottomOffset)
# Draw the alternating-color background first and get plotXScale
plotXScale = self.drawGraphBackground(canvas, gifmap, offset=newoffset, zoom= zoom, startMb=startMb, endMb = endMb)
# Draw X axis
self.drawXAxis(fd, canvas, drawAreaHeight, gifmap, plotXScale, showLocusForm, offset=newoffset, zoom= zoom, startMb=startMb, endMb = endMb)
# Draw QTL curve
self.drawQTL(canvas, drawAreaHeight, gifmap, plotXScale, offset=newoffset, zoom= zoom, startMb=startMb, endMb = endMb)
#draw legend
if self.multipleInterval:
self.drawMultiTraitName(fd, canvas, gifmap, showLocusForm, offset=newoffset)
elif self.legendChecked:
self.drawLegendPanel(fd, canvas, offset=newoffset)
else:
pass
#draw position, no need to use a separate function
if fd.genotype.Mbmap:
self.drawProbeSetPosition(canvas, plotXScale, offset=newoffset)
return gifmap
# functions for manhattam plot of markers
def drawManhattanPlotForPLINK(self, canvas, drawAreaHeight, gifmap, plotXScale, offset= (40, 120, 80, 10), zoom = 1, startMb = None, endMb = None,plinkResultDict={},thresholdPvalue=-1):
xLeftOffset, xRightOffset, yTopOffset, yBottomOffset = offset
plotWidth = canvas.size[0] - xLeftOffset - xRightOffset
plotHeight = canvas.size[1] - yTopOffset - yBottomOffset
fontZoom = zoom
if zoom == 2:
fontZoom = 1.5
# INTERCROSS = (self.genotype.type=="intercross")
INTERCROSS ='' #??????
ChrLengthDistList = self.ChrLengthMbList
drawRegionDistance = self.ChrLengthMbSum
GraphInterval=self.GraphInterval
pvalueHeightThresh = drawAreaHeight - 80 #ZS: Otherwise the plot gets very close to the chromosome labels
#draw the pvalue scale
#We first determine whether or not we are using a sliding scale.
#If so, we need to compute the maximum pvalue value to determine where the max y-value should be, and call this pvalueMax.
#pvalueTop is then defined to be above the pvalueMax by enough to add one additional pvalueScale increment.
#if we are using a set-scale, then we set pvalueTop to be the user's value, and pvalueMax doesn't matter.
# for human data we use p value instead of lrs
pValueList=[]
for key in plinkResultDict:
valueList = plinkResultDict[key]
for item in valueList:
pValue = item[-1]
pValueList.append(pValue)
formattedPValueList=[]
for pValue in pValueList:
try:
pValue=float(pValue)
except:
pValue =1
formattedpValue = -math.log10(pValue)
formattedPValueList.append(formattedpValue)
#sliding scale
pvalueMax = max(formattedPValueList)
#pvalueMax =pvalueMax +1
# no permutation result for plink func: GenReport()
pvalueMin = int(-math.log10(thresholdPvalue))
if pvalueMax> 100:
pvalueScale = 20.0
elif pvalueMax > 20:
pvalueScale = 5.0
elif pvalueMax > 7.5:
pvalueScale = 2.5
else:
pvalueScale = 1.0
# the base line for x-axis is -log(thresholdPvalue)
pvalueAxisList = Plot.frange(pvalueMin, pvalueMax, pvalueScale)
#make sure the user's value appears on the y-axis
#ZS: There is no way to do this without making the position of the points not directly proportional to a given distance on the y-axis
#tempPvalueMax=round(pvalueMax)
tempPvalueMax = pvalueAxisList[len(pvalueAxisList)-1] + pvalueScale
pvalueAxisList.append(tempPvalueMax)
#ZS: I don't understand this; the if statement will be true for any number that isn't exactly X.5.
#if abs(tempPvalueMax-pvalueMax) <0.5:
# tempPvalueMax=tempPvalueMax+1
# pvalueAxisList.append(tempPvalueMax)
#draw the "pvalue" string to the left of the axis
pvalueScaleFont=pid.Font(ttf="verdana", size=14*fontZoom, bold=0)
pvalueLODFont=pid.Font(ttf="verdana", size=14*zoom*1.5, bold=0)
yZero = yTopOffset + plotHeight
#yAxis label display area
yAxis_label ='-log(P)'
canvas.drawString(yAxis_label, xLeftOffset - canvas.stringWidth("999.99", font=pvalueScaleFont) - 10*zoom, \
yZero - 150, font=pvalueLODFont, color=pid.black, angle=90)
for i,item in enumerate(pvalueAxisList):
ypvalue = yZero - (float(i)/float(len(pvalueAxisList) - 1)) * pvalueHeightThresh
canvas.drawLine(xLeftOffset, ypvalue, xLeftOffset - 4, ypvalue, color=self.LRS_COLOR, width=1*zoom)
scaleStr = "%2.1f" % item
#added by NL 6-24-2011:Y-axis scale display
canvas.drawString(scaleStr, xLeftOffset-4-canvas.stringWidth(scaleStr, font=pvalueScaleFont)-5, ypvalue+3, font=pvalueScaleFont, color=self.LRS_COLOR)
ChrList=self.ChrList
startPosX = xLeftOffset
for i, chr in enumerate(ChrList):
if plinkResultDict.has_key(chr):
plinkresultList = plinkResultDict[chr]
m = 0
#add by NL 06-24-2011: for mahanttam plot
symbolFont = pid.Font(ttf="fnt_bs", size=5,bold=0)
# color for point in each chr
chrCount=len(ChrList)
chrColorDict =self.getColorForMarker(chrCount=chrCount,flag=1)
for j, item in enumerate(plinkresultList):
try :
mb=float(item[1])/1000000.0
except:
mb=0
try :
pvalue =float(item[-1])
except:
pvalue =1
try:
snpName = item[0]
except:
snpName=''
formattedPvalue = -math.log10(pvalue)
Xc = startPosX + (mb-startMb)*plotXScale
Yc = yZero - (formattedPvalue-pvalueMin)*pvalueHeightThresh/(tempPvalueMax - pvalueMin)
canvas.drawString("5", Xc-canvas.stringWidth("5",font=symbolFont)/2+1,Yc+2,color=chrColorDict[i], font=symbolFont)
m += 1
startPosX += (ChrLengthDistList[i]+GraphInterval)*plotXScale
canvas.drawLine(xLeftOffset, yZero, xLeftOffset, yTopOffset, color=self.LRS_COLOR, width=1*zoom) #the blue line running up the y axis
def drawQTL(self, canvas, drawAreaHeight, gifmap, plotXScale, offset= (40, 120, 80, 10), zoom = 1, startMb = None, endMb = None):
xLeftOffset, xRightOffset, yTopOffset, yBottomOffset = offset
plotWidth = canvas.size[0] - xLeftOffset - xRightOffset
plotHeight = canvas.size[1] - yTopOffset - yBottomOffset
fontZoom = zoom
if zoom == 2:
fontZoom = 1.5
INTERCROSS = (self.genotype.type=="intercross")
ChrLengthDistList = self.ChrLengthMbList
GraphInterval=self.GraphInterval
LRSHeightThresh = drawAreaHeight
AdditiveHeightThresh = drawAreaHeight/2
DominanceHeightThresh = drawAreaHeight/2
#draw the LRS scale
#We first determine whether or not we are using a sliding scale.
#If so, we need to compute the maximum LRS value to determine where the max y-value should be, and call this LRSMax.
#LRSTop is then defined to be above the LRSMax by enough to add one additional LRSScale increment.
#if we are using a set-scale, then we set LRSTop to be the user's value, and LRSMax doesn't matter.
if self.LRS_LOD == 'LOD':
lodm = self.LODFACTOR
else:
lodm = 1.0
if self.lrsMax <= 0: #sliding scale
LRSMax = max(map(max, self.qtlresults)).lrs
#genotype trait will give infinite LRS
LRSMax = min(LRSMax, webqtlConfig.MAXLRS)
LRSMax = max(self.significance, LRSMax)
else:
LRSMax = self.lrsMax*lodm
if LRSMax/lodm > 100:
LRSScale = 20.0
elif LRSMax/lodm > 20:
LRSScale = 5.0
elif LRSMax/lodm > 7.5:
LRSScale = 2.5
else:
LRSScale = 1.0
LRSAxisList = Plot.frange(LRSScale, LRSMax/lodm, LRSScale)
#make sure the user's value appears on the y-axis
#update by NL 6-21-2011: round the LOD value to 100 when LRSMax is equal to 460
LRSAxisList.append(round(LRSMax/lodm))
#draw the "LRS" or "LOD" string to the left of the axis
LRSScaleFont=pid.Font(ttf="verdana", size=14*fontZoom, bold=0)
LRSLODFont=pid.Font(ttf="verdana", size=14*zoom*1.5, bold=0)
yZero = yTopOffset + plotHeight
#yAxis label display area
canvas.drawString(self.LRS_LOD, xLeftOffset - canvas.stringWidth("999.99", font=LRSScaleFont) - 10*zoom, \
yZero - 150, font=LRSLODFont, color=pid.black, angle=90)
for item in LRSAxisList:
yLRS = yZero - (item*lodm/LRSMax) * LRSHeightThresh
canvas.drawLine(xLeftOffset, yLRS, xLeftOffset - 4, yLRS, color=self.LRS_COLOR, width=1*zoom)
scaleStr = "%2.1f" % item
#added by NL 6-24-2011:Y-axis scale display
canvas.drawString(scaleStr, xLeftOffset-4-canvas.stringWidth(scaleStr, font=LRSScaleFont)-5, yLRS+3, font=LRSScaleFont, color=self.LRS_COLOR)
#"Significant" and "Suggestive" Drawing Routine
# ======= Draw the thick lines for "Significant" and "Suggestive" ===== (crowell: I tried to make the SNPs draw over these lines, but piddle wouldn't have it...)
if self.permChecked and not self.multipleInterval:
significantY = yZero - self.significance*LRSHeightThresh/LRSMax
suggestiveY = yZero - self.suggestive*LRSHeightThresh/LRSMax
startPosX = xLeftOffset
for i, _chr in enumerate(self.genotype):
rightEdge = int(startPosX + self.ChrLengthDistList[i]*plotXScale - self.SUGGESTIVE_WIDTH/1.5)
#added by NL 6-24-2011:draw suggestive line (grey one)
canvas.drawLine(startPosX+self.SUGGESTIVE_WIDTH/1.5, suggestiveY, rightEdge, suggestiveY, color=self.SUGGESTIVE_COLOR,
width=self.SUGGESTIVE_WIDTH*zoom, clipX=(xLeftOffset, xLeftOffset + plotWidth-2))
#added by NL 6-24-2011:draw significant line (pink one)
canvas.drawLine(startPosX+self.SUGGESTIVE_WIDTH/1.5, significantY, rightEdge, significantY, color=self.SIGNIFICANT_COLOR,
width=self.SIGNIFICANT_WIDTH*zoom, clipX=(xLeftOffset, xLeftOffset + plotWidth-2))
sugg_coords = "%d, %d, %d, %d" % (startPosX, suggestiveY-2, rightEdge + 2*zoom, suggestiveY+2)
sig_coords = "%d, %d, %d, %d" % (startPosX, significantY-2, rightEdge + 2*zoom, significantY+2)
if self.LRS_LOD == 'LRS':
sugg_title = "Suggestive LRS = %0.2f" % self.suggestive
sig_title = "Significant LRS = %0.2f" % self.significance
else:
sugg_title = "Suggestive LOD = %0.2f" % (self.suggestive/4.61)
sig_title = "Significant LOD = %0.2f" % (self.significance/4.61)
Areas1 = HT.Area(shape='rect',coords=sugg_coords,title=sugg_title)
Areas2 = HT.Area(shape='rect',coords=sig_coords,title=sig_title)
gifmap.areas.append(Areas1)
gifmap.areas.append(Areas2)
startPosX += (self.ChrLengthDistList[i]+self.GraphInterval)*plotXScale
if self.multipleInterval:
lrsEdgeWidth = 1
else:
additiveMax = max(map(lambda X : abs(X.additive), self.qtlresults[0]))
if INTERCROSS:
dominanceMax = max(map(lambda X : abs(X.dominance), self.qtlresults[0]))
else:
dominanceMax = -1
lrsEdgeWidth = 2
for i, qtlresult in enumerate(self.qtlresults):
m = 0
startPosX = xLeftOffset
thisLRSColor = self.colorCollection[i]
#add by NL 06-24-2011: for mahanttam plot
symbolFont = pid.Font(ttf="fnt_bs", size=5,bold=0)
for j, _chr in enumerate(self.genotype):
chrCount=len(self.genotype)
chrColorDict =self.getColorForMarker(chrCount=chrCount,flag=1)
LRSCoordXY = []
AdditiveCoordXY = []
DominanceCoordXY = []
for k, _locus in enumerate(_chr):
if self.plotScale == 'physic':
Xc = startPosX + (_locus.Mb-startMb)*plotXScale
else:
Xc = startPosX + (_locus.cM-_chr[0].cM)*plotXScale
# updated by NL 06-18-2011:
# fix the over limit LRS graph issue since genotype trait may give infinite LRS;
# for any lrs is over than 460(LRS max in this system), it will be reset to 460
if qtlresult[m].lrs> 460 or qtlresult[m].lrs=='inf':
Yc = yZero - webqtlConfig.MAXLRS*LRSHeightThresh/LRSMax
else:
Yc = yZero - qtlresult[m].lrs*LRSHeightThresh/LRSMax
LRSCoordXY.append((Xc, Yc))
#add by NL 06-24-2011: for mahanttam plot
#self.significance/4.61 consider chr and LOD
# significantY = yZero - self.significance*LRSHeightThresh/LRSMax
# if Yc >significantY:
# canvas.drawString(":", Xc-canvas.stringWidth(":",font=symbolFont)/2+1,Yc+2,color=pid.black, font=symbolFont)
# else:
# canvas.drawString(":", Xc-canvas.stringWidth(":",font=symbolFont)/2+1,Yc+2,color=pid.black, font=symbolFont)
# add by NL 06-27-2011: eliminate imputed value when locus name is equal to '-'
if (qtlresult[m].locus.name) and (qtlresult[m].locus.name!=' - '):
canvas.drawString("5", Xc-canvas.stringWidth("5",font=symbolFont)/2+1,Yc+2,color=chrColorDict[j], font=symbolFont)
if not self.multipleInterval and self.additiveChecked:
Yc = yZero - qtlresult[m].additive*AdditiveHeightThresh/additiveMax
AdditiveCoordXY.append((Xc, Yc))
if not self.multipleInterval and INTERCROSS and self.additiveChecked:
Yc = yZero - qtlresult[m].dominance*DominanceHeightThresh/dominanceMax
DominanceCoordXY.append((Xc, Yc))
m += 1
startPosX += (ChrLengthDistList[j]+GraphInterval)*plotXScale
###draw additive scale
if not self.multipleInterval and self.additiveChecked:
additiveScaleFont=pid.Font(ttf="verdana",size=12*fontZoom,bold=0)
additiveScale = Plot.detScaleOld(0,additiveMax)
additiveStep = (additiveScale[1]-additiveScale[0])/additiveScale[2]
additiveAxisList = Plot.frange(0, additiveScale[1], additiveStep)
maxAdd = additiveScale[1]
addPlotScale = AdditiveHeightThresh/additiveMax
additiveAxisList.append(additiveScale[1])
for item in additiveAxisList:
additiveY = yZero - item*addPlotScale
canvas.drawLine(xLeftOffset + plotWidth,additiveY,xLeftOffset+4+ plotWidth,additiveY,color=self.ADDITIVE_COLOR_POSITIVE, width=1*zoom)
scaleStr = "%2.3f" % item
canvas.drawString(scaleStr,xLeftOffset + plotWidth +6,additiveY+5,font=additiveScaleFont,color=self.ADDITIVE_COLOR_POSITIVE)
canvas.drawLine(xLeftOffset+plotWidth,additiveY,xLeftOffset+plotWidth,yZero,color=self.ADDITIVE_COLOR_POSITIVE, width=1*zoom)
canvas.drawLine(xLeftOffset, yZero, xLeftOffset, yTopOffset, color=self.LRS_COLOR, width=1*zoom) #the blue line running up the y axis
def drawGraphBackgroundForPLINK(self, canvas, gifmap, offset= (80, 120, 80, 50), zoom = 1, startMb = None, endMb = None,plinkResultDict={} ):
xLeftOffset, xRightOffset, yTopOffset, yBottomOffset = offset
plotWidth = canvas.size[0] - xLeftOffset - xRightOffset
plotHeight = canvas.size[1] - yTopOffset - yBottomOffset
fontZoom = zoom
if zoom == 2:
fontZoom = 1.5
#calculate plot scale
#XZ: all of these global variables should be passed from function signiture
ChrLengthDistList = self.ChrLengthMbList
drawRegionDistance = self.ChrLengthMbSum
GraphInterval=self.GraphInterval
ChrList =self.ChrList
#multiple chromosome view
plotXScale = plotWidth / ((len(ChrList)-1)*GraphInterval + drawRegionDistance)
startPosX = xLeftOffset
chrLabelFont=pid.Font(ttf="verdana",size=24*fontZoom,bold=0)
for i, _chr in enumerate(ChrList):
if (i % 2 == 0):
theBackColor = self.GRAPH_BACK_DARK_COLOR
else:
theBackColor = self.GRAPH_BACK_LIGHT_COLOR
# NL:resize chr width for drawing
if float(ChrLengthDistList[i])<90:
ChrLengthDistList[i]=90
#draw the shaded boxes and the sig/sug thick lines
canvas.drawRect(startPosX, yTopOffset, startPosX + ChrLengthDistList[i]*plotXScale, \
yTopOffset+plotHeight, edgeColor=pid.gainsboro,fillColor=theBackColor)
chrNameWidth = canvas.stringWidth(_chr, font=chrLabelFont)
chrStartPix = startPosX + (ChrLengthDistList[i]*plotXScale -chrNameWidth)/2
chrEndPix = startPosX + (ChrLengthDistList[i]*plotXScale +chrNameWidth)/2
canvas.drawString(_chr, chrStartPix, yTopOffset +20,font = chrLabelFont,color=pid.dimgray)
COORDS = "%d,%d,%d,%d" %(chrStartPix, yTopOffset, chrEndPix,yTopOffset +20)
#add by NL 09-03-2010
HREF = "javascript:changeView(%d,%s);" % (i,ChrLengthDistList)
Areas = HT.Area(shape='rect',coords=COORDS,href=HREF)
gifmap.areas.append(Areas)
startPosX += (ChrLengthDistList[i]+GraphInterval)*plotXScale
return plotXScale
def drawGraphBackground(self, canvas, gifmap, offset= (80, 120, 80, 50), zoom = 1, startMb = None, endMb = None):
##conditions
##multiple Chromosome view
##single Chromosome Physical
##single Chromosome Genetic
xLeftOffset, xRightOffset, yTopOffset, yBottomOffset = offset
plotWidth = canvas.size[0] - xLeftOffset - xRightOffset
plotHeight = canvas.size[1] - yTopOffset - yBottomOffset
fontZoom = zoom
if zoom == 2:
fontZoom = 1.5
#calculate plot scale
if self.plotScale != 'physic':
self.ChrLengthDistList = self.ChrLengthCMList
drawRegionDistance = self.ChrLengthCMSum
else:
self.ChrLengthDistList = self.ChrLengthMbList
drawRegionDistance = self.ChrLengthMbSum
if self.selectedChr > -1: #single chromosome view
spacingAmt = plotWidth/13.5
i = 0
for startPix in Plot.frange(xLeftOffset, xLeftOffset+plotWidth, spacingAmt):
if (i % 2 == 0):
theBackColor = self.GRAPH_BACK_DARK_COLOR
else:
theBackColor = self.GRAPH_BACK_LIGHT_COLOR
i += 1
canvas.drawRect(startPix, yTopOffset, min(startPix+spacingAmt, xLeftOffset+plotWidth), \
yTopOffset+plotHeight, edgeColor=theBackColor, fillColor=theBackColor)
drawRegionDistance = self.ChrLengthDistList[self.selectedChr]
self.ChrLengthDistList = [drawRegionDistance]
if self.plotScale == 'physic':
plotXScale = plotWidth / (endMb-startMb)
else:
plotXScale = plotWidth / drawRegionDistance
else: #multiple chromosome view
plotXScale = plotWidth / ((len(self.genotype)-1)*self.GraphInterval + drawRegionDistance)
startPosX = xLeftOffset
chrLabelFont=pid.Font(ttf="verdana",size=24*fontZoom,bold=0)
for i, _chr in enumerate(self.genotype):
if (i % 2 == 0):
theBackColor = self.GRAPH_BACK_DARK_COLOR
else:
theBackColor = self.GRAPH_BACK_LIGHT_COLOR
#draw the shaded boxes and the sig/sug thick lines
canvas.drawRect(startPosX, yTopOffset, startPosX + self.ChrLengthDistList[i]*plotXScale, \
yTopOffset+plotHeight, edgeColor=pid.gainsboro,fillColor=theBackColor)
chrNameWidth = canvas.stringWidth(_chr.name, font=chrLabelFont)
chrStartPix = startPosX + (self.ChrLengthDistList[i]*plotXScale -chrNameWidth)/2
chrEndPix = startPosX + (self.ChrLengthDistList[i]*plotXScale +chrNameWidth)/2
canvas.drawString(_chr.name, chrStartPix, yTopOffset +20,font = chrLabelFont,color=pid.dimgray)
COORDS = "%d,%d,%d,%d" %(chrStartPix, yTopOffset, chrEndPix,yTopOffset +20)
#add by NL 09-03-2010
HREF = "javascript:changeView(%d,%s);" % (i,self.ChrLengthMbList)
Areas = HT.Area(shape='rect',coords=COORDS,href=HREF)
gifmap.areas.append(Areas)
startPosX += (self.ChrLengthDistList[i]+self.GraphInterval)*plotXScale
return plotXScale
# XZ: The only difference of function drawXAxisForPLINK and function drawXAxis are the function name and the self.plotScale condition.
def drawXAxisForPLINK(self, fd, canvas, drawAreaHeight, gifmap, plotXScale, showLocusForm, offset= (40, 120, 80, 10), zoom = 1, startMb = None, endMb = None):
xLeftOffset, xRightOffset, yTopOffset, yBottomOffset = offset
plotWidth = canvas.size[0] - xLeftOffset - xRightOffset
plotHeight = canvas.size[1] - yTopOffset - yBottomOffset
yZero = canvas.size[1] - yBottomOffset
fontZoom = zoom
if zoom == 2:
fontZoom = 1.5
#Parameters
ChrLengthDistList = self.ChrLengthMbList
GraphInterval=self.GraphInterval
NUM_MINOR_TICKS = 5 # Number of minor ticks between major ticks
X_MAJOR_TICK_THICKNESS = 2
X_MINOR_TICK_THICKNESS = 1
X_AXIS_THICKNESS = 1*zoom
# ======= Alex: Draw the X-axis labels (megabase location)
MBLabelFont = pid.Font(ttf="verdana", size=12*fontZoom, bold=0)
xMajorTickHeight = 15 # How high the tick extends below the axis
xMinorTickHeight = 5*zoom
xAxisTickMarkColor = pid.black
xAxisLabelColor = pid.black
fontHeight = 12*fontZoom # How tall the font that we're using is
spacingFromLabelToAxis = 20
spacingFromLineToLabel = 3
if self.plotScale == 'physic':
strYLoc = yZero + spacingFromLabelToAxis + canvas.fontHeight(MBLabelFont)
###Physical single chromosome view
if self.selectedChr > -1:
graphMbWidth = endMb - startMb
XScale = Plot.detScale(startMb, endMb)
XStart, XEnd, XStep = XScale
if XStep < 8:
XStep *= 2
spacingAmtX = spacingAmt = (XEnd-XStart)/XStep
j = 0
while abs(spacingAmtX -int(spacingAmtX)) >= spacingAmtX/100.0 and j < 6:
j += 1
spacingAmtX *= 10
formatStr = '%%2.%df' % j
for counter, _Mb in enumerate(Plot.frange(XStart, XEnd, spacingAmt / NUM_MINOR_TICKS)):
if _Mb < startMb or _Mb > endMb:
continue
Xc = xLeftOffset + plotXScale*(_Mb - startMb)
if counter % NUM_MINOR_TICKS == 0: # Draw a MAJOR mark, not just a minor tick mark
canvas.drawLine(Xc, yZero, Xc, yZero+xMajorTickHeight, color=xAxisTickMarkColor, width=X_MAJOR_TICK_THICKNESS) # Draw the MAJOR tick mark
labelStr = str(formatStr % _Mb) # What Mbase location to put on the label
strWidth = canvas.stringWidth(labelStr, font=MBLabelFont)
drawStringXc = (Xc - (strWidth / 2.0))
canvas.drawString(labelStr, drawStringXc, strYLoc, font=MBLabelFont, color=xAxisLabelColor, angle=0)
else:
canvas.drawLine(Xc, yZero, Xc, yZero+xMinorTickHeight, color=xAxisTickMarkColor, width=X_MINOR_TICK_THICKNESS) # Draw the MINOR tick mark
# end else
###Physical genome wide view
else:
distScale = 0
startPosX = xLeftOffset
for i, distLen in enumerate(ChrLengthDistList):
if distScale == 0: #universal scale in whole genome mapping
if distLen > 75:
distScale = 25
elif distLen > 30:
distScale = 10
else:
distScale = 5
for tickdists in range(distScale, ceil(distLen), distScale):
canvas.drawLine(startPosX + tickdists*plotXScale, yZero, startPosX + tickdists*plotXScale, yZero + 7, color=pid.black, width=1*zoom)
canvas.drawString(str(tickdists), startPosX+tickdists*plotXScale, yZero + 10*zoom, color=pid.black, font=MBLabelFont, angle=270)
startPosX += (ChrLengthDistList[i]+GraphInterval)*plotXScale
megabaseLabelFont = pid.Font(ttf="verdana", size=14*zoom*1.5, bold=0)
canvas.drawString("Megabases", xLeftOffset + (plotWidth -canvas.stringWidth("Megabases", font=megabaseLabelFont))/2,
strYLoc + canvas.fontHeight(MBLabelFont) + 5*zoom, font=megabaseLabelFont, color=pid.black)
pass
canvas.drawLine(xLeftOffset, yZero, xLeftOffset+plotWidth, yZero, color=pid.black, width=X_AXIS_THICKNESS) # Draw the X axis itself
def drawXAxis(self, fd, canvas, drawAreaHeight, gifmap, plotXScale, showLocusForm, offset= (40, 120, 80, 10), zoom = 1, startMb = None, endMb = None):
xLeftOffset, xRightOffset, yTopOffset, yBottomOffset = offset
plotWidth = canvas.size[0] - xLeftOffset - xRightOffset
plotHeight = canvas.size[1] - yTopOffset - yBottomOffset
yZero = canvas.size[1] - yBottomOffset
fontZoom = zoom
if zoom == 2:
fontZoom = 1.5
#Parameters
NUM_MINOR_TICKS = 5 # Number of minor ticks between major ticks
X_MAJOR_TICK_THICKNESS = 2
X_MINOR_TICK_THICKNESS = 1
X_AXIS_THICKNESS = 1*zoom
# ======= Alex: Draw the X-axis labels (megabase location)
MBLabelFont = pid.Font(ttf="verdana", size=12*fontZoom, bold=0)
xMajorTickHeight = 15 # How high the tick extends below the axis
xMinorTickHeight = 5*zoom
xAxisTickMarkColor = pid.black
xAxisLabelColor = pid.black
fontHeight = 12*fontZoom # How tall the font that we're using is
spacingFromLabelToAxis = 20
spacingFromLineToLabel = 3
if self.plotScale == 'physic':
strYLoc = yZero + spacingFromLabelToAxis + canvas.fontHeight(MBLabelFont)
###Physical single chromosome view
if self.selectedChr > -1:
graphMbWidth = endMb - startMb
XScale = Plot.detScale(startMb, endMb)
XStart, XEnd, XStep = XScale
if XStep < 8:
XStep *= 2
spacingAmtX = spacingAmt = (XEnd-XStart)/XStep
j = 0
while abs(spacingAmtX -int(spacingAmtX)) >= spacingAmtX/100.0 and j < 6:
j += 1
spacingAmtX *= 10
formatStr = '%%2.%df' % j
for counter, _Mb in enumerate(Plot.frange(XStart, XEnd, spacingAmt / NUM_MINOR_TICKS)):
if _Mb < startMb or _Mb > endMb:
continue
Xc = xLeftOffset + plotXScale*(_Mb - startMb)
if counter % NUM_MINOR_TICKS == 0: # Draw a MAJOR mark, not just a minor tick mark
canvas.drawLine(Xc, yZero, Xc, yZero+xMajorTickHeight, color=xAxisTickMarkColor, width=X_MAJOR_TICK_THICKNESS) # Draw the MAJOR tick mark
labelStr = str(formatStr % _Mb) # What Mbase location to put on the label
strWidth = canvas.stringWidth(labelStr, font=MBLabelFont)
drawStringXc = (Xc - (strWidth / 2.0))
canvas.drawString(labelStr, drawStringXc, strYLoc, font=MBLabelFont, color=xAxisLabelColor, angle=0)
else:
canvas.drawLine(Xc, yZero, Xc, yZero+xMinorTickHeight, color=xAxisTickMarkColor, width=X_MINOR_TICK_THICKNESS) # Draw the MINOR tick mark
# end else
###Physical genome wide view
else:
distScale = 0
startPosX = xLeftOffset
for i, distLen in enumerate(self.ChrLengthDistList):
if distScale == 0: #universal scale in whole genome mapping
if distLen > 75:
distScale = 25
elif distLen > 30:
distScale = 10
else:
distScale = 5
for tickdists in range(distScale, ceil(distLen), distScale):
canvas.drawLine(startPosX + tickdists*plotXScale, yZero, startPosX + tickdists*plotXScale, yZero + 7, color=pid.black, width=1*zoom)
canvas.drawString(str(tickdists), startPosX+tickdists*plotXScale, yZero + 10*zoom, color=pid.black, font=MBLabelFont, angle=270)
startPosX += (self.ChrLengthDistList[i]+self.GraphInterval)*plotXScale
megabaseLabelFont = pid.Font(ttf="verdana", size=14*zoom*1.5, bold=0)
canvas.drawString("Megabases", xLeftOffset + (plotWidth -canvas.stringWidth("Megabases", font=megabaseLabelFont))/2,
strYLoc + canvas.fontHeight(MBLabelFont) + 5*zoom, font=megabaseLabelFont, color=pid.black)
pass
else:
ChrAInfo = []
preLpos = -1
distinctCount = 0.0
if len(self.genotype) > 1:
for i, _chr in enumerate(self.genotype):
thisChr = []
Locus0CM = _chr[0].cM
nLoci = len(_chr)
if nLoci <= 8:
for _locus in _chr:
if _locus.name != ' - ':
if _locus.cM != preLpos:
distinctCount += 1
preLpos = _locus.cM
thisChr.append([_locus.name, _locus.cM-Locus0CM])
else:
for j in (0, nLoci/4, nLoci/2, nLoci*3/4, -1):
while _chr[j].name == ' - ':
j += 1
if _chr[j].cM != preLpos:
distinctCount += 1
preLpos = _chr[j].cM
thisChr.append([_chr[j].name, _chr[j].cM-Locus0CM])
ChrAInfo.append(thisChr)
else:
for i, _chr in enumerate(self.genotype):
thisChr = []
Locus0CM = _chr[0].cM
for _locus in _chr:
if _locus.name != ' - ':
if _locus.cM != preLpos:
distinctCount += 1
preLpos = _locus.cM
thisChr.append([_locus.name, _locus.cM-Locus0CM])
ChrAInfo.append(thisChr)
stepA = (plotWidth+0.0)/distinctCount
LRectWidth = 10
LRectHeight = 3
offsetA = -stepA
lineColor = pid.lightblue
startPosX = xLeftOffset
for j, ChrInfo in enumerate(ChrAInfo):
preLpos = -1
for i, item in enumerate(ChrInfo):
Lname,Lpos = item
if Lpos != preLpos:
offsetA += stepA
differ = 1
else:
differ = 0
preLpos = Lpos
Lpos *= plotXScale
if self.selectedChr > -1:
Zorder = i % 5
else:
Zorder = 0
if differ:
canvas.drawLine(startPosX+Lpos,yZero,xLeftOffset+offsetA,\
yZero+25, color=lineColor)
canvas.drawLine(xLeftOffset+offsetA,yZero+25,xLeftOffset+offsetA,\
yZero+40+Zorder*(LRectWidth+3),color=lineColor)
rectColor = pid.orange
else:
canvas.drawLine(xLeftOffset+offsetA, yZero+40+Zorder*(LRectWidth+3)-3,\
xLeftOffset+offsetA, yZero+40+Zorder*(LRectWidth+3),color=lineColor)
rectColor = pid.deeppink
canvas.drawRect(xLeftOffset+offsetA, yZero+40+Zorder*(LRectWidth+3),\
xLeftOffset+offsetA-LRectHeight,yZero+40+Zorder*(LRectWidth+3)+LRectWidth,\
edgeColor=rectColor,fillColor=rectColor,edgeWidth = 0)
COORDS="%d,%d,%d,%d"%(xLeftOffset+offsetA-LRectHeight, yZero+40+Zorder*(LRectWidth+3),\
xLeftOffset+offsetA,yZero+40+Zorder*(LRectWidth+3)+LRectWidth)
HREF="javascript:showDatabase3('%s','%s','%s','');" % (showLocusForm,fd.RISet+"Geno", Lname)
Areas=HT.Area(shape='rect',coords=COORDS,href=HREF, title="Locus : " + Lname)
gifmap.areas.append(Areas)
##piddle bug
if j == 0:
canvas.drawLine(startPosX,yZero,startPosX,yZero+40, color=lineColor)
startPosX += (self.ChrLengthDistList[j]+self.GraphInterval)*plotXScale
canvas.drawLine(xLeftOffset, yZero, xLeftOffset+plotWidth, yZero, color=pid.black, width=X_AXIS_THICKNESS) # Draw the X axis itself
def getColorForMarker(self, chrCount,flag):# no change is needed
chrColorDict={}
for i in range(chrCount):
if flag==1: # display blue and lightblue intercross
chrColorDict[i]=pid.black
elif flag==0:
if (i%2==0):
chrColorDict[i]=pid.blue
else:
chrColorDict[i]=pid.lightblue
else:#display different color for different chr
if i in [0,8,16]:
chrColorDict[i]=pid.black
elif i in [1,9,17]:
chrColorDict[i]=pid.red
elif i in [2,10,18]:
chrColorDict[i]=pid.lightgreen
elif i in [3,11,19]:
chrColorDict[i]=pid.blue
elif i in [4,12]:
chrColorDict[i]=pid.lightblue
elif i in [5,13]:
chrColorDict[i]=pid.hotpink
elif i in [6,14]:
chrColorDict[i]=pid.gold
elif i in [7,15]:
chrColorDict[i]=pid.grey
return chrColorDict
def drawProbeSetPosition(self, canvas, plotXScale, offset= (40, 120, 80, 10), zoom = 1, startMb = None, endMb = None):
if len(self.traitList) != 1:
return
xLeftOffset, xRightOffset, yTopOffset, yBottomOffset = offset
plotWidth = canvas.size[0] - xLeftOffset - xRightOffset
plotHeight = canvas.size[1] - yTopOffset - yBottomOffset
yZero = canvas.size[1] - yBottomOffset
fontZoom = zoom
if zoom == 2:
fontZoom = 1.5
try:
Chr = self.traitList[0].chr # self.traitListChr =self.traitList[0].chr=_vals need to change to chrList and mbList
Mb = self.traitList[0].mb # self.traitListMb =self.traitList[0].mb=_vals
except:
return
if self.plotScale == 'physic':
if self.selectedChr > -1:
if self.genotype[0].name != Chr or Mb < self.startMb or Mb > self.endMb:
return
else:
locPixel = xLeftOffset + (Mb-self.startMb)*plotXScale
else:
locPixel = xLeftOffset
for i, _chr in enumerate(self.genotype):
if _chr.name != Chr:
locPixel += (self.ChrLengthDistList[i] + self.GraphInterval)*plotXScale
else:
locPixel += Mb*plotXScale
break
else:
if self.selectedChr > -1:
if self.genotype[0].name != Chr:
return
else:
for i, _locus in enumerate(self.genotype[0]):
#the trait's position is on the left of the first genotype
if i==0 and _locus.Mb >= Mb:
locPixel=-1
break
#the trait's position is between two traits
if i > 0 and self.genotype[0][i-1].Mb < Mb and _locus.Mb >= Mb:
locPixel = xLeftOffset + plotXScale*(self.genotype[0][i-1].cM+(_locus.cM-self.genotype[0][i-1].cM)*(Mb -self.genotype[0][i-1].Mb)/(_locus.Mb-self.genotype[0][i-1].Mb))
break
#the trait's position is on the right of the last genotype
if i==len(self.genotype[0]) and Mb>=_locus.Mb:
locPixel = -1
else:
locPixel = xLeftOffset
for i, _chr in enumerate(self.genotype):
if _chr.name != Chr:
locPixel += (self.ChrLengthDistList[i] + self.GraphInterval)*plotXScale
else:
locPixel += (Mb*(_chr[-1].cM-_chr[0].cM)/self.ChrLengthCMList[i])*plotXScale
break
if locPixel >= 0:
traitPixel = ((locPixel, yZero), (locPixel-6, yZero+12), (locPixel+6, yZero+12))
canvas.drawPolygon(traitPixel, edgeColor=pid.black, fillColor=self.TRANSCRIPT_LOCATION_COLOR, closed=1)
if self.legendChecked:
startPosY = 15
nCol = 2
smallLabelFont = pid.Font(ttf="trebuc", size=12, bold=1)
leftOffset = xLeftOffset+(nCol-1)*200
canvas.drawPolygon(((leftOffset+6, startPosY-6), (leftOffset, startPosY+6), (leftOffset+12, startPosY+6)), edgeColor=pid.black, fillColor=self.TRANSCRIPT_LOCATION_COLOR, closed=1)
canvas.drawString("Sequence Site", (leftOffset+15), (startPosY+5), smallLabelFont, self.TOP_RIGHT_INFO_COLOR)
# build dict based on plink result, key is chr, value is list of [snp,BP,pValue]
def getPlinkResultDict(self,outputFileName='',thresholdPvalue=-1,ChrOrderIdNameDict={}):
ChrList =self.ChrList
plinkResultDict={}
plinkResultfp = open("%s%s.qassoc"% (webqtlConfig.TMPDIR, outputFileName), "rb")
headerLine=plinkResultfp.readline()# read header line
line = plinkResultfp.readline()
valueList=[] # initialize value list, this list will include snp, bp and pvalue info
pValueList=[]
count=0
while line:
#convert line from str to list
lineList=self.buildLineList(line=line)
# only keep the records whose chromosome name is in db
if ChrOrderIdNameDict.has_key(int(lineList[0])) and lineList[-1] and lineList[-1].strip()!='NA':
chrName=ChrOrderIdNameDict[int(lineList[0])]
snp = lineList[1]
BP = lineList[2]
pValue = float(lineList[-1])
pValueList.append(pValue)
if plinkResultDict.has_key(chrName):
valueList=plinkResultDict[chrName]
# pvalue range is [0,1]
if thresholdPvalue >=0 and thresholdPvalue<=1:
if pValue < thresholdPvalue:
valueList.append((snp,BP,pValue))
count+=1
plinkResultDict[chrName]=valueList
valueList=[]
else:
if thresholdPvalue>=0 and thresholdPvalue<=1:
if pValue < thresholdPvalue:
valueList.append((snp,BP,pValue))
count+=1
if valueList:
plinkResultDict[chrName]=valueList
valueList=[]
line =plinkResultfp.readline()
else:
line=plinkResultfp.readline()
if pValueList:
minPvalue= min(pValueList)
else:
minPvalue=0
return count,minPvalue,plinkResultDict
######################################################
# input: line: str,one line read from file
# function: convert line from str to list;
# output: lineList list
#######################################################
def buildLineList(self,line=None):
lineList = string.split(string.strip(line),' ')# irregular number of whitespaces between columns
lineList =[ item for item in lineList if item <>'']
lineList = map(string.strip, lineList)
return lineList
#added by NL: automatically generate pheno txt file for PLINK based on strainList passed from dataEditing page
def genPhenoTxtFileForPlink(self,phenoFileName='', RISetName='', probesetName='', valueDict={}):
pedFileStrainList=self.getStrainNameFromPedFile(RISetName=RISetName)
outputFile = open("%s%s.txt"%(webqtlConfig.TMPDIR,phenoFileName),"wb")
headerLine = 'FID\tIID\t%s\n'%probesetName
outputFile.write(headerLine)
newValueList=[]
#if valueDict does not include some strain, value will be set to -9999 as missing value
for item in pedFileStrainList:
try:
value=valueDict[item]
value=str(value).replace('value=','')
value=value.strip()
except:
value=-9999
newValueList.append(value)
newLine=''
for i, strain in enumerate(pedFileStrainList):
j=i+1
value=newValueList[i]
newLine+='%s\t%s\t%s\n'%(strain, strain, value)
if j%1000==0:
outputFile.write(newLine)
newLine=''
if newLine:
outputFile.write(newLine)
outputFile.close()
# get strain name from ped file in order
def getStrainNameFromPedFile(self, RISetName=''):
pedFileopen= open("%splink/%s.ped"%(webqtlConfig.GENODIR, RISetName),"r")
line =pedFileopen.readline()
strainNameList=[]
while line:
lineList=string.split(string.strip(line),'\t')
lineList=map(string.strip,lineList)
strainName=lineList[0]
strainNameList.append(strainName)
line =pedFileopen.readline()
return strainNameList
################################################################
# Generate Chr list, Chr OrderId and Retrieve Length Information
################################################################
def getChrNameOrderIdLength(self,RISet=''):
try:
query = """
Select
Chr_Length.Name,Chr_Length.OrderId,Length from Chr_Length, InbredSet
where
Chr_Length.SpeciesId = InbredSet.SpeciesId AND
InbredSet.Name = '%s'
Order by OrderId
""" % (RISet)
self.cursor.execute(query)
results =self.cursor.fetchall()
ChrList=[]
ChrLengthMbList=[]
ChrNameOrderIdDict={}
ChrOrderIdNameDict={}
for item in results:
ChrList.append(item[0])
ChrNameOrderIdDict[item[0]]=item[1] # key is chr name, value is orderId
ChrOrderIdNameDict[item[1]]=item[0] # key is orderId, value is chr name
ChrLengthMbList.append(item[2])
except:
ChrList=[]
ChrNameOrderIdDict={}
ChrLengthMbList=[]
return ChrList,ChrNameOrderIdDict,ChrOrderIdNameDict,ChrLengthMbList
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