# Exclude some sequences from the calculation
        # ------------------------------------------------------------------------------------------

        # Skip sequences with partial CDS annotations
        #if(r.exists("CDS:taxid:%d:protid:%s:partial" % (taxIdForProcessing, protId))):
        #    skipped += 1
        #    continue

        #if( not r.exists(nativeCdsSeqIdKey % (taxIdForProcessing, protId)) ):
        #    skipped +=1
        #    continue

        cds = CDSHelper(taxIdForProcessing, protId)

        seqLength = cds.length()
        stopCodonPos = cds.CDSlength()

        if seqLength is None:
            print(
                "Warning: Could not find CDS length entry for taxid=%d, protid=%s"
                % (taxIdForProcessing, protId))
            skipped += 1
            stats['skipped-cds-length-missing'] += 1
            continue

        # Skip sequences with length <40nt (window width)
        if (seqLength < windowWidth + 1):
            print("short seq")
            stats['skipped-short-seq'] += 1
            skipped += 1
            continue
    def calculateMissingWindowsForSequence(self, taxId, protId, seqIds, requestedShuffleIds, firstWindow, lastWindowStart, windowStep, reference="begin", shuffleType=db.Sources.ShuffleCDSv2_python, debug=False):

        timerForPreFolding.start()
        logging.warning("Parameters: %d %s %s %s %d %d %s %d" % (taxId, protId, seqIds, requestedShuffleIds, lastWindowStart, windowStep, reference, shuffleType))
        f = self._logfile

        assert(len(seqIds)>0)
        assert(len(seqIds)==len(requestedShuffleIds))

        # ------------------------------------------------------------------------
        # Obtain species-dependent properties needed for some calculations
        # ----------------
        # Optimal Temp
        optimalSpeciesGrowthTemperature = None
        if( self._seriesSourceNumber == db.Sources.RNAfoldEnergy_SlidingWindow40_v2_native_temp ):
            (numericalProp, _) = getSpeciesTemperatureInfo(taxId)
            optimalSpeciesGrowthTemperature = numericalProp[0]

            if optimalSpeciesGrowthTemperature is None:
                raise Exception("No temperature value for taxid={}, can't calculate native-temperature folding profile...".format(taxId))
            else:
                optimalSpeciesGrowthTemperature = float(optimalSpeciesGrowthTemperature)
                assert(optimalSpeciesGrowthTemperature >= -30.0 and optimalSpeciesGrowthTemperature <= 150.0)
        # ----------------
        # Genomic translation table
        genomicTranslationTable = None
        if( self._seriesSourceNumber in (db.Sources.StopCodon_content_SlidingWindow30, db.Sources.StopCodon_content_SlidingWindow40, db.Sources.StopCodon_content_SlidingWindow50 )):
            genomicTranslationTable = getSpeciesTranslationTable(taxId)
            assert(genomicTranslationTable>0 and genomicTranslationTable<=31)
            

        if( reference != "begin" and reference != "end" and reference != "stop3utr"):
            timerForPreFolding.stop()
            e = "Specificed profile reference '%s' is not supported!" % reference
            logging.error(e)
            raise Exception(e)

        # We will process all listed shuffle-ids for the following protein record
        if( reference == "begin" or reference == "end" ):
            regionOfInterest = RegionsOfInterset.CDSonly
        elif reference == "stop3utr":
            regionOfInterest = RegionsOfInterset.CDSand3UTR
        else:
            assert(False)
            
        cds = CDSHelper( taxId, protId, regionOfInterest=regionOfInterest )

        if( cds.length() < self._windowWidth ):
            e = "Refusing to process item %s because the sequence length (%d nt) is less than the window size (%d nt)\n" % (itemToProcess, cds.length(), self._windowWidth)
            f.write(e)
            logging.error(e)
            timerForPreFolding.stop()
            raise Exception(e)

        # Create a list of the windows we need to calculate for this CDS
        if reference == "begin":
            requestedWindowStarts = frozenset(list(range(0, min(lastWindowStart+1, cds.length()-self._windowWidth-1), windowStep)))
            if( len(requestedWindowStarts) == 0):
                e = "No windows exist for calculation taxid=%d, protId=%s, CDS-length=%d, lastWindowStart=%d, windowStep=%d, windowWidth=%d - Skipping...\n" % (taxId, protId, cds.length(), lastWindowStart, windowStep, self._windowWidth)
                f.write(e)
                logging.error(e)
                timerForPreFolding.stop()
                raise Exception(e)
            
        elif reference == "end":
            lastPossibleWindowStart = cds.length() - self._windowWidth #+ 1  # disregard lastWindowStart when reference=="end"
            #lastWindowCodonStart = (lastPossibleWindowStart-3)-(lastPossibleWindowStart-3)%3

            #lastPossibleWindowStart = seqLength - windowWidth # + 1  # disregard lastWindowStart when reference=="end"
            requestedWindowStarts = frozenset([x for x in range(lastPossibleWindowStart % windowStep, lastPossibleWindowStart+1, windowStep) if x>=lastWindowStart])

        elif reference == "stop3utr":
            seqLength = cds.length()
            stopCodonPos = cds.CDSlength()
            
            isRequired = [1 if abs(pos-stopCodonPos)<((lastWindowStart//2)*windowStep) else 0 for pos in range(0, seqLength - self._windowWidth, windowStep)]
            requestedWindowStarts = frozenset( compress( range(seqLength), isRequired ) )
            

            #requestedWindowStarts = frozenset(range(lastWindowCodonStart % windowStep, lastWindowCodonStart, windowStep))
            #pass
        else:
            assert(False)

        # First, read available results (for all shuffle-ids) in JSON format
        # Array is indexed by shuffle-id, so results not requested will be represented by None (as will requested items that have no results yet).
        logging.info("DEBUG: requestedShuffleIds (%d items): %s\n" % (len(requestedShuffleIds), requestedShuffleIds))
        existingResults = cds.getCalculationResult2( self._seriesSourceNumber, requestedShuffleIds, True, shuffleType=shuffleType )
        #assert(len(existingResults) >= len(requestedShuffleIds))  # The returned array must be at least as large as the requested ids list
        assert(len(existingResults) == len(requestedShuffleIds))
        logging.info("requestedShuffleIds: %s" % requestedShuffleIds)
        logging.info("existingResults.keys(): %s" % list(existingResults.keys()))
        assert(frozenset(requestedShuffleIds)==frozenset(list(existingResults.keys())))
        #existingResults = [None] * (max(requestedShuffleIds)+1)
        logging.info("DEBUG: existingResults (%d items): %s\n" % (len(existingResults), existingResults))

        # Check for which of the requested shuffle-ids there are values missing
        shuffleIdsToProcess = {}
        for shuffleId, r in list(existingResults.items()):
            if r is None:
                # There are no existing results for shuffled-id n. If it was requested, it should be calculated now (including all windows)
                if shuffleId in requestedShuffleIds:
                    shuffleIdsToProcess[shuffleId] = list(requestedWindowStarts)
                    
                timerForPreFolding.stop()
                
                # ------------------------------------------------------------------------------------
                continue   # TODO - verify this line; should we abort this sequence by throwing????
                # ------------------------------------------------------------------------------------

            logging.info("/// shuffleId r = %d %s" % (shuffleId, r))
            logging.info("r[MFE-profile] %s" % r["MFE-profile"])
            
            # Check the existing results for this shuffle
            alreadyProcessedWindowStarts = frozenset( [i for i,x in enumerate(r["MFE-profile"] ) if x is not None] ) # Get the indices (=window starts) of all non-None values
            missingWindows = requestedWindowStarts - alreadyProcessedWindowStarts # Are there any requested windows that are not already computed?
            if( missingWindows ): 
                shuffleIdsToProcess[shuffleId] = missingWindows

        if( not shuffleIdsToProcess):
            e = "All requested shuffle-ids in (taxId: %d, protId: %s, seqs: %s) seem to have already been processed. Skipping...\n" % (taxId, protId, str(list(zip(seqIds, requestedShuffleIds))) )
            logging.warning(e)
            timerForPreFolding.stop()
            return
        logging.info("DEBUG: shuffleIdsToProcess (%d items): %s\n" % (len(shuffleIdsToProcess), shuffleIdsToProcess))

        logging.info("DEBUG: Before (%d items): %s\n" % (len(existingResults), existingResults))
        # Initialize new results records
        for shuffleId in list(shuffleIdsToProcess.keys()):
            if existingResults[shuffleId] is None:
                logging.info(seqIds)
                logging.info(requestedShuffleIds)
                logging.info(shuffleId)
                thisSeqId = seqIds[ requestedShuffleIds.index(shuffleId) ]
                    
                existingResults[shuffleId] = { "id": "%s/%s/%d/%d" % (taxId, protId, thisSeqId, shuffleId), "seq-crc": None, "MFE-profile": [], "MeanMFE": None, "v": 2, "shuffle-type":shuffleType }
        logging.info("DEBUG: existingResults (%d items): %s\n" % (len(existingResults),existingResults) )
        timerForPreFolding.stop()

        # Load the sequences of all shuffle-ids we need to work on
        # TODO - combine loading of multiple sequences into one DB operation
        for shuffleId, record in list(existingResults.items()):
            if record is None:
                logging.info("DEBUG: skipping empty results record for shuffleId={}".format(shuffleId))
                continue
            timerForPreFolding.start()

            seq = None
            annotatedSeqId = None
            # Get the sequence for this entry
            if( shuffleId < 0 ):
                seq = cds.sequence()
                annotatedSeqId = cds.seqId()
            else:
                seq = cds.getShuffledSeq(shuffleId, shuffleType)
                annotatedSeqId = cds.getShuffledSeqId(shuffleId, shuffleType)

            if( seq is None or (not seq is None and len(seq)==0 )):
                seq2 = cds.getShuffledSeq2( annotatedSeqId )
                seq3 = cds._fetchSequence( annotatedSeqId )
                seq4 = cds._cache.get("%d:seq"%annotatedSeqId)
                if not seq4 is None:
                    del cds._cache["%d:seq"%annotatedSeqId]
                seq5 = cds.getShuffledSeq2( annotatedSeqId )
                e = "Got empty sequence for shuffleId=%d, seqId=%d, taxId=%d, protId=%s, numShuffled=%d, ids[%d:%d]=%s, len(seq2)=%d, len(seq3)=%d, len(seq4)=%d, len(seq5)=%d" % (shuffleId, annotatedSeqId, taxId, protId, len(cds.shuffledSeqIds()), shuffleId-2, shuffleId+2, cds.shuffledSeqIds()[shuffleId-2:shuffleId+2], len(seq2) if not seq2 is None else -1, len(seq3) if not seq3 is None else -1, len(seq4) if not seq4 is None else -1, len(seq5) if not seq5 is None else -1 )
                logging.error(e)
                timerForPreFolding.stop()
                raise Exception(e)

            #
            # Disabled - calculation needn't include the native sequence...
            #
            #if( annotatedSeqId not in seqIds ):
            #    e = "Error: SeqId specified in queue item %s does not match annotated seq-id %d\n" % (itemToProcess, annotatedSeqId)
            #    f.write(e)
            #    f.write("Current shuffle-id: %d\n" % shuffleId)
            #    f.write("Ids in existing results:\n")
            #    for shuffleId, record in enumerate(existingResults):
            #        f.write(" %d) %s\n" % (shuffleId, record['id']))
            #    f.write("Debug info:\n")
            #    f.write("\n".join(cds.getDebugInfo()))
            #    f.write("\n")
            #    f.write("Skipping...\n")
            #    print("Skipping...")
            #    raise Exception(e)

            expectedSeqLength = cds.length()
            if( not expectedSeqLength is None ):
                if( expectedSeqLength != len(seq) ):
                    e = "Warning: taxid=%d, protid=%s, seqid=%d - unexpected length %d (expected: %d)\n" % (taxId, protId, annotatedSeqId, len(seq), expectedSeqLength)
                    f.write(e)
                    logging.error(e)
                    timerForPreFolding.stop()
                    raise Exception(e)

            if( len(seq) < self._windowWidth ):
                # Sequence is shorter than required window; skip
                e = "Warning: skipping sequence because it is shorter than the requested window...\n"
                f.write(e)
                logging.error(e)
                timerForPreFolding.stop()
                raise Exception(e)

            logging.info("DEBUG: Processing item taxId=%d, protId=%s, shuffle=%d (length=%d, %d windows)...\n" % (taxId, protId, shuffleId, len(seq), len(requestedWindowStarts)))

            # TODO - Remove any old value stored in this key?

            # Skip this for now
            # This will be made redundant by completing the "updating" implementation
            #
            #if( cds.isCalculationDone( seriesSourceNumber, shuffleId )):
            #    # Sufficient data seems to exist. Skip...
            #    f.write("Item %s appears to be already completed, skipping..." % itemToProcess)
            #    continue

            logging.info(seq[:50])
            #f.write("\n")

            MFEprofile = record["MFE-profile"]
            #f.write("Profile: %s\n" % MFEprofile)

            # Make sure the profile array contains enough entries for all new windows (and possibly, if windows are non-contiguous, entries between them that we are not going to compute right now)
            if( len(MFEprofile) < max(requestedWindowStarts) ):
                entriesToAdd = max(requestedWindowStarts) - len(MFEprofile) + 1
                MFEprofile.extend( [None] * entriesToAdd )
            assert(len(MFEprofile) >= max(requestedWindowStarts))

            stats = RunningStats()
            stats.extend([x for x in MFEprofile if x is not None])

            timerForPreFolding.stop()
            timerForFolding.start()
            for start in requestedWindowStarts:
                fragment = seq[start:(start+self._windowWidth)]
                assert(len(fragment)==self._windowWidth)

                if self._seriesSourceNumber in (db.Sources.RNAfoldEnergy_SlidingWindow30_v2, db.Sources.RNAfoldEnergy_SlidingWindow40_v2, db.Sources.RNAfoldEnergy_SlidingWindow50_v2):
                    # Calculate the RNA folding energy. This is the computation-heavy part.
                    #strct, energy = RNA.fold(fragment)
                    result = RNAfold_direct(fragment)
                    assert(result <= 0.0)

                elif self._seriesSourceNumber == db.Sources.RNAfoldEnergy_SlidingWindow40_v2_native_temp:
                    # Calculate the RNA folding energy. This is the computation-heavy part.
                    #strct, energy = RNA.fold(fragment)
                    result = RNAfold_direct(fragment, explicitCalculationTemperature = optimalSpeciesGrowthTemperature)
                    assert(result <= 0.0)

                elif self._seriesSourceNumber == db.Sources.GC_content_SlidingWindow40:
                    result = calcWindowGCContent( fragment )
                    assert( isnan(result) or (result >= 0.0 and result <= 1.0) )
                    
                elif self._seriesSourceNumber == db.Sources.Purine_content_SlidingWindow40:
                    result = calcWindowPurineContent( fragment )
                    assert( isnan(result) or (result >= 0.0 and result <= 1.0) )
                    
                elif self._seriesSourceNumber in (db.Sources.StopCodon_content_SlidingWindow30, db.Sources.StopCodon_content_SlidingWindow40, db.Sources.StopCodon_content_SlidingWindow50):
                    result = calcWindowStopCodonContent( fragment, translationTable=genomicTranslationTable, phase=start%3 )
                    assert( result >= 0.0 and result <= 1.0 )

                    
                elif self._seriesSourceNumber == db.Sources.TEST_StepFunction_BeginReferenced:
                    if shuffleId < 0:
                        result = 0
                    else:
                        result = start%50 - 20
                
                elif self._seriesSourceNumber == db.Sources.TEST_StepFunction_EndReferenced:
                    if shuffleId < 0:
                        result = 0
                    else:
                        result = (expectedSeqLength - self._windowWidth - start)%50 - 20

                else:
                    logging.error("Received unknown seriesSourceNumber {}".format(self._seriesSourceNumber))
                    assert(False)
                    
                # Store the calculation result
                #print("%d:%s --> %f" % (taxId, protId, energy))

                stats.push(result)
                MFEprofile[start] = result

            #print("///////////////////  shuffleId={} (len={}) //////////////////////////".format(shuffleId, expectedSeqLength))
            if debug:
                prettyPrintProfile(MFEprofile)

            timerForFolding.stop()
            timerForPostFolding.start()

            # Format
            crc = getCrc(seq)
            #result = """{"id":"%s","seq-crc":%d,"MFE-profile":[%s],"MeanMFE":%.6g,v:2}""" % (itemToProcess, crc, ",".join(map(lambda x: "%.3g" % x, MFEprofile)), stats.mean())
            record["seq-crc"] = crc
            record["MFE-profile"] = [round4(x) for x in MFEprofile] # Round items down to save space (these are not exact numbers anyway)
            record["MeanMFE"] = stats.mean()
            
            if reference == "stop3utr":
                record["stop-codon-pos"] = cds.CDSlength()
                
            result = json.dumps(record)

            f.write(result)
            f.write("\n")

            if( not self._debugDoneWriteResults):
                cds.saveCalculationResult2( self._seriesSourceNumber, result, annotatedSeqId, False )
                
            timerForPostFolding.stop()

            
        timerForPostFolding.start()
        
        if( not self._debugDoneWriteResults):
            cds.commitChanges()
            
        timerForPostFolding.stop()
                newValues = sum([1 for x in profile1 if not x is None])
                windowsAddedToProfiles.update( (newValues,) )


                rawRecordId = updateRecord[1]['id']
                try:
                    recordId = splitLongSequenceIdentifier(rawRecordId)
                            
                except Exception as e:
                    err[ErrorTypes.UpdateRecordFormatError] += 1
                    badUpdateRecords.add(updateRecord[2])
                    print(e)
                    continue

                cds = CDSHelper(recordId[0], recordId[1] )
                cdsLength = cds.CDSlength()

                newPositions = [x[0] for x in enumerate(profile1) if not x[1] is None]

                for pos in newPositions:
                    windowsAddedToProfiles_DistanceFromStart.update( (pos,) )
                    windowsAddedToProfiles_DistanceFromEnd.update( (cdsLength-pos,) )
                    windowsAddedToProfiles_FrameRelativeToStart.update( (pos%10,) )
                    windowsAddedToProfiles_FrameRelativeToEnd.update( ((cdsLength-pos)%10,) )
                

        if(rl()):
            print(total, err, recordsByTaxId)

        # DEBUG ONLY #### DEBUG ONLY #### DEBUG ONLY #### DEBUG ONLY #### DEBUG ONLY #### DEBUG ONLY #### DEBUG ONLY #
        #if( total > 90000):
Exemplo n.º 4
0
    def randomize(self, nucleotideSeq: str, protId: str) -> (int, float, str):

        #print("-----------"*5)
        cds = CDSHelper(self.taxId, protId)

        # Get metadata from genome model
        #gm = cds.getGenomeModel()

        #found = gm.findFeatureById( protId )
        #if found is None:
        #    raise Exception("Failed to find feature matching protein-id={} in genome model".format(protId))
        #(moleculeId, currFeature)  = found

        #if gm.moleculeModels[moleculeId].find3PrimeFlankingRegion( currFeature, debug=True ) is None:
        #    pass
        #print((moleculeId, feature))

        cdsLengthNt = cds.CDSlength()
        assert (cdsLengthNt % 3 == 0)
        flankingRegionLengthNt = cds.flankingRegion3UtrLength()
        nextCDSOppositeStrand = cds.nextCDSOnOppositeStrand()

        # Case 1 (no overlap):
        #                     +--------intergenic--------+
        #                     |                          |
        # +-------CDS1--------+                          +------------CDS2-----------+
        # |                   |                          |                           |
        # +===================+--------------------------+===========================+
        # |                   |                          |                           |
        # +===================+--------------------------+===========================+
        # |<---cdsLengthNt--->|<-flankingRegionLengthNt->|                           |
        # |                              (>= 0)                                      |
        # |<---------------------------cds.totalLength()---------------------------->|

        # Case 2 (overlap):
        #                     +--------------------------CDS2-------------------------+
        #                     |                                                       |
        # +---------------------CDS1----------------------+                           |
        # |                   |                           |                           |
        # +===================+===========================+===========================+
        # |                   |                           |                           |
        # +===================+===========================+===========================+
        # |                   |<-flankingRegionLengthNt-->|                           |
        # |                              (<= 0)           |                           |
        # |<----------------cdsLengthNt------------------>|                           |
        # |<----------------------------cds.totalLength()---------------------------->|

        if flankingRegionLengthNt < 0 and -flankingRegionLengthNt > cdsLengthNt:
            #flankingRegionLengthNt = -cdsLengthNt
            raise Exception("Next CDS is fully overlapping...")

        #-----------------------------------------------------------------------------
        # Randomize the "main" CDS
        #-----------------------------------------------------------------------------
        # First, determine which region to randomize...
        if (not self.constantOverlaps) or (
                flankingRegionLengthNt >=
                0):  # no overlap, or overlap should be randomized
            CDSseq = nucleotideSeq[:cdsLengthNt]
            assert (len(CDSseq) == cdsLengthNt)
        else:  # constant overlaps requested and this CDS is overlapping the next. Remove the overlap from the CDS (it will not be randomized):
            lastNucBeforeOverlap = cdsLengthNt + flankingRegionLengthNt
            assert (lastNucBeforeOverlap < cdsLengthNt)
            lastNucToRandomize = lastNucBeforeOverlap - (lastNucBeforeOverlap %
                                                         3)
            CDSseq = nucleotideSeq[:lastNucToRandomize]
            assert (len(CDSseq) % 3 == 0)

        # Then, do the randomization...
        (CDSpermCount, CDSidentity,
         randomizedCDS) = self.cdsRand.randomizeAmbiguousSequence(CDSseq)

        # Finally, add the non-randomized part of the CDS (if any)
        if (not self.constantOverlaps) or (
                flankingRegionLengthNt >=
                0):  # no overlap, or overlap should be randomized
            pass
        else:  # constant overlaps requested and this CDS is overlapping the next.
            randomizedCDS = randomizedCDS + nucleotideSeq[
                lastNucToRandomize:cdsLengthNt]
            assert (len(randomizedCDS) % 3 == 0)

        assert (
            len(randomizedCDS) == cdsLengthNt
        )  # the length of the resulting sequence matches the original CDS sequence

        #-----------------------------------------------------------------------------
        # Randomize the 3'UTR
        #-----------------------------------------------------------------------------
        if flankingRegionLengthNt > 0:
            _3UTRseq = nucleotideSeq[cdsLengthNt:cdsLengthNt +
                                     flankingRegionLengthNt]
            assert (len(_3UTRseq) == flankingRegionLengthNt)
            (UTRpermCount, UTRidentity,
             randomizedUTR) = self.utrRand.randomizeAmbiguousSequence(_3UTRseq)
        else:
            _3UTRseq = ""
            UTRpermCount = 1
            UTRidentity = 1.0
            randomizedUTR = ""

        #-----------------------------------------------------------------------------
        # Randomize the downstream CDS
        #-----------------------------------------------------------------------------
        nextCDSseq = nucleotideSeq[
            cdsLengthNt +
            flankingRegionLengthNt:]  # Should work for positive and negative length UTRs
        assert (len(nextCDSseq) % 3 == 0)
        #nextCDSseq = nextCDSseq[(len(nextCDSseq)%3):]  # remove partial codons from the start (caused due to the overlap; we can only randomize each codon as part of one CDS, although in the overlap region codons belong to two CDSs...)
        if nextCDSOppositeStrand:
            nextCDSseq = str(Seq(nextCDSseq, generic_dna).reverse_complement())
        assert (len(nextCDSseq) % 3 == 0)
        (nextCDSpermCount, nextCDSidentity, randomizedNextCDS
         ) = self.cdsRand.randomizeAmbiguousSequence(nextCDSseq)
        if nextCDSOppositeStrand:  # if the next CDS is on the opposite strand, revcomp it back to its original frame
            randomizedNextCDS = str(
                Seq(randomizedNextCDS, generic_dna).reverse_complement())
        if flankingRegionLengthNt < 0:
            randomizedNextCDS = randomizedNextCDS[-flankingRegionLengthNt:]

        totalPerms = CDSpermCount * UTRpermCount * nextCDSpermCount

        totalIdentity = ((CDSidentity * len(CDSseq)) +
                         (UTRidentity * len(_3UTRseq)) +
                         (nextCDSidentity * len(nextCDSseq))) / (
                             len(CDSseq) + len(_3UTRseq) + len(nextCDSseq))

        return (totalPerms, totalIdentity,
                randomizedCDS + randomizedUTR + randomizedNextCDS)