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# pylmm is a python-based linear mixed-model solver with applications to GWAS

# Copyright (C) 2013  Nicholas A. Furlotte (nick.furlotte@gmail.com)
#
# 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.

# You should have received a copy of the GNU Affero General Public License
# along with this program.  If not, see <http://www.gnu.org/licenses/>.


import os
import sys
import numpy as np
import struct
import pdb

class plink:
    def __init__(self,fbase,kFile=None,phenoFile=None,type='b',normGenotype=True,readKFile=False):

        self.fbase = fbase
        self.type = type
        self.indivs = self.getIndivs(self.fbase,type)
        self.kFile = kFile
        self.phenos = None
        self.normGenotype = normGenotype
        self.phenoFile = phenoFile
        # Originally I was using the fastLMM style that has indiv IDs embedded.
        # NOW I want to use this module to just read SNPs so I'm allowing
        # the programmer to turn off the kinship reading.
        self.readKFile = readKFile

        if self.kFile:
            self.kFile = kFile
            if self.readKFile: self.K = self.readKinship(self.kFile)
        elif os.path.isfile("%s.kin" % fbase):
            self.kFile = "%s.kin" %fbase
            if self.readKFile: self.K = self.readKinship(self.kFile)
        else:
            self.kFile = None
            self.K = None

        self.getPhenos(self.phenoFile)

        self.fhandle = None
        self.snpFileHandle = None

    def __del__(self):
        if self.fhandle: self.fhandle.close()
        if self.snpFileHandle: self.snpFileHandle.close()

    def getSNPIterator(self):
        if not self.type == 'b':
            sys.stderr.write("Have only implemented this for binary plink files (bed)\n")
            return

        # get the number of snps
        file = self.fbase + '.bim'
        i = 0
        f = open(file,'r')
        for line in f: i += 1
        f.close()
        self.numSNPs = i
        self.have_read = 0
        self.snpFileHandle = open(file,'r')

        self.BytestoRead = self.N / 4 + (self.N % 4 and 1 or 0)
        self._formatStr = 'c'*self.BytestoRead

        file = self.fbase + '.bed'
        self.fhandle = open(file,'rb')

        magicNumber = self.fhandle.read(2)
        order = self.fhandle.read(1)
        if not order == '\x01':
            sys.stderr.write("This is not in SNP major order - you did not handle this case\n")
            raise StopIteration

        return self

    def __iter__(self): return self.getSNPIterator()

    def next(self):
        if self.have_read == self.numSNPs: raise StopIteration
        X = self.fhandle.read(self.BytestoRead)
        XX = [bin(ord(x)) for x in struct.unpack(self._formatStr,X)]
        self.have_read += 1
        return self.formatBinaryGenotypes(XX,self.normGenotype),self.snpFileHandle.readline().strip().split()[1]

    def formatBinaryGenotypes(self,X,norm=True):
        D = { \
              '00': 0.0, \
              '10': 0.5, \
              '11': 1.0, \
              '01': np.nan \
           }

        D_tped = { \
              '00': '1 1', \
              '10': '1 2', \
              '11': '2 2', \
              '01': '0 0' \
           }

        #D = D_tped

        G = []
        for x in X:
            if not len(x) == 10:
                xx = x[2:]
                x = '0b' + '0'*(8 - len(xx)) + xx
            a,b,c,d = (x[8:],x[6:8],x[4:6],x[2:4])
            L = [D[y] for y in [a,b,c,d]]
            G += L
        # only take the leading values because whatever is left should be null
        G = G[:self.N]
        G = np.array(G)
        if norm: G = self.normalizeGenotype(G)
        return G

    def normalizeGenotype(self,G):
        x = True - np.isnan(G)
        m = G[x].mean()
        s = np.sqrt(G[x].var())
        G[np.isnan(G)] = m
        G = (G - m) / s
        return G

    def getPhenos(self,phenoFile=None):
        if not phenoFile: self.phenoFile = phenoFile = self.fbase+".phenos"
        if not os.path.isfile(phenoFile):
            sys.stderr.write("Could not find phenotype file: %s\n" % (phenoFile))
            return
        f = open(phenoFile,'r')
        keys = []
        P = []
        for line in f:
            v = line.strip().split()
            keys.append((v[0],v[1]))
            P.append([(x == 'NA' or x == '-9') and np.nan or float(x) for x in v[2:]])
        f.close()
        P = np.array(P)

        # reorder to match self.indivs
        D = {}
        L = []
        for i in range(len(keys)): D[keys[i]] = i
        for i in range(len(self.indivs)):
            if not D.has_key(self.indivs[i]): continue
            L.append(D[self.indivs[i]])
        P = P[L,:]

        self.phenos = P
        return P

    def getIndivs(self,base,type='b'):
        if type == 't': famFile = "%s.tfam" % base
        else: famFile = "%s.fam" % base

        keys = []
        i = 0
        f = open(famFile,'r')
        for line in f:
            v = line.strip().split()
            famId = v[0]
            indivId = v[1]
            k = (famId.strip(),indivId.strip())
            keys.append(k)
            i += 1
        f.close()

        self.N = len(keys)
        sys.stderr.write("Read %d individuals from %s\n" % (self.N, famFile))

        return keys

    def readKinship(self,kFile):
        # Assume the fastLMM style
        # This will read in the kinship matrix and then reorder it
        # according to self.indivs - additionally throwing out individuals
        # that are not in both sets
        if self.indivs == None or len(self.indivs) == 0:
            sys.stderr.write("Did not read any individuals so can't load kinship\n")
            return

        sys.stderr.write("Reading kinship matrix from %s\n" % (kFile) )

        f = open(kFile,'r')
        # read indivs
        v = f.readline().strip().split("\t")[1:]
        keys = [tuple(y.split()) for y in v]
        D = {}
        for i in range(len(keys)): D[keys[i]] = i

        # read matrix
        K = []
        for line in f: K.append([float(x) for x in line.strip().split("\t")[1:]])
        f.close()
        K  = np.array(K)

        # reorder to match self.indivs
        L = []
        KK = []
        X = []
        for i in range(len(self.indivs)):
            if not D.has_key(self.indivs[i]): X.append(self.indivs[i])
            else:
                KK.append(self.indivs[i])
                L.append(D[self.indivs[i]])
        K = K[L,:][:,L]
        self.indivs = KK
        self.indivs_removed = X
        if len(self.indivs_removed): sys.stderr.write("Removed %d individuals that did not appear in Kinship\n" % (len(self.indivs_removed)))
        return K

    def getCovariates(self,covFile=None):
        if not os.path.isfile(covFile):
            sys.stderr.write("Could not find covariate file: %s\n" % (phenoFile))
            return
        f = open(covFile,'r')
        keys = []
        P = []
        for line in f:
            v = line.strip().split()
            keys.append((v[0],v[1]))
            P.append([x == 'NA' and np.nan or float(x) for x in v[2:]])
        f.close()
        P = np.array(P)

        # reorder to match self.indivs
        D = {}
        L = []
        for i in range(len(keys)): D[keys[i]] = i
        for i in range(len(self.indivs)):
            if not D.has_key(self.indivs[i]): continue
            L.append(D[self.indivs[i]])
        P = P[L,:]

        return P