PPGrowth

class PAMI.partialPeriodicPatternInMultipleTimeSeries.PPGrowth.PPGrowth(iFile, periodicSupport, period, sep='\t')[source]

Bases: _partialPeriodicPatterns

Description:

PPGrowth is one of the fundamental algorithm to discover periodic-frequent patterns in a transactional database.

Reference:

C. Saideep, R. Uday Kiran, K. Zettsu, P. Fournier-Viger, M. Kitsuregawa and P. Krishna Reddy, “Discovering Periodic Patterns in Irregular Time Series,” 2019 International Conference on Data Mining Workshops (ICDMW), 2019,

pp. 1020-1028, doi: 10.1109/ICDMW.2019.00147.

Parameters:

iFile – str : Name of the Input file to mine complete set of periodic frequent pattern’s
oFile – str : Name of the output file to store complete set of periodic frequent pattern’s
sep – str : This variable is used to distinguish items from one another in a transaction. The default seperator is tab space. However, the users can override their default separator.

Attributes:

iFilefile: Name of the Input file or path of the input file
oFilefile: Name of the output file or path of the output file
minSup: int or float or str: The user can specify minSup either in count or proportion of database size. If the program detects the data type of minSup is integer, then it treats minSup is expressed in count. Otherwise, it will be treated as float. Example: minSup=10 will be treated as integer, while minSup=10.0 will be treated as float
maxPer: int or float or str: The user can specify maxPer either in count or proportion of database size. If the program detects the data type of maxPer is integer, then it treats maxPer is expressed in count. Otherwise, it will be treated as float. Example: maxPer=10 will be treated as integer, while maxPer=10.0 will be treated as float
sepstr: This variable is used to distinguish items from one another in a transaction. The default seperator is tab space or . However, the users can override their default separator.
memoryUSSfloat: To store the total amount of USS memory consumed by the program
memoryRSSfloat: To store the total amount of RSS memory consumed by the program
startTime:float: To record the start time of the mining process
endTime:float: To record the completion time of the mining process
Databaselist: To store the transactions of a database in list
mapSupportDictionary: To maintain the information of item and their frequency
lnoint: To represent the total no of transaction
treeclass: To represents the Tree class
itemSetCountint: To represents the total no of patterns
finalPatternsdict: To store the complete patterns

Methods:

mine(): Mining process will start from here
getPatterns(): Complete set of patterns will be retrieved with this function
save(oFile): Complete set of periodic-frequent patterns will be loaded in to a output file
getPatternsAsDataFrame(): Complete set of periodic-frequent patterns will be loaded in to a dataframe
getMemoryUSS(): Total amount of USS memory consumed by the mining process will be retrieved from this function
getMemoryRSS(): Total amount of RSS memory consumed by the mining process will be retrieved from this function
getRuntime(): Total amount of runtime taken by the mining process will be retrieved from this function
creatingItemSets(fileName): Scans the dataset and stores in a list format
PeriodicFrequentOneItem(): Extracts the one-periodic-frequent patterns from database
updateDatabases(): Update the database by removing aperiodic items and sort the Database by item decreased support
buildTree(): After updating the Database, remaining items will be added into the tree by setting root node as null
convert(): to convert the user specified value

Executing the code on terminal:

Format:

(.venv) $ python3 PPGrowth.py <inputFile> <outputFile> <minSup> <maxPer>

Examples:

(.venv) $  python3 PPGrowth.py sampleTDB.txt patterns.txt 0.3 0.4

Sample run of importing the code:

from PAMI.periodicFrequentPattern.basic import PPGrowth as alg

obj = alg.PPGrowth(iFile, minSup, maxPer)

obj.mine()

periodicFrequentPatterns = obj.getPatterns()

print(“Total number of Periodic Frequent Patterns:”, len(periodicFrequentPatterns))

obj.save(oFile)

Df = obj.getPatternsAsDataFrame()

memUSS = obj.getMemoryUSS()

print(“Total Memory in USS:”, memUSS)

memRSS = obj.getMemoryRSS()

print(“Total Memory in RSS”, memRSS)

run = obj.getRuntime()

print(“Total ExecutionTime in seconds:”, run)

Credits:

The complete program was written by P.Likhitha under the supervision of Professor Rage Uday Kiran.

Mine()[source]: Mining process will start from this function

getMemoryRSS()[source]

Total amount of RSS memory consumed by the mining process will be retrieved from this function

Returns:: returning RSS memory consumed by the mining process
Return type:: float

getMemoryUSS()[source]

Total amount of USS memory consumed by the mining process will be retrieved from this function

Returns:: returning USS memory consumed by the mining process
Return type:: float

getPatterns()[source]

Function to send the set of periodic-frequent patterns after completion of the mining process

Returns:: returning periodic-frequent patterns
Return type:: dict

getPatternsAsDataFrame()[source]

Storing final periodic-frequent patterns in a dataframe

Returns:: returning periodic-frequent patterns in a dataframe
Return type:: pd.DataFrame

getRuntime()[source]

Calculating the total amount of runtime taken by the mining process

Returns:: returning total amount of runtime taken by the mining process
Return type:: float

printResults()[source]: This function is used to print the results

save(outFile)[source]

Complete set of periodic-frequent patterns will be loaded in to a output file

Parameters:: outFile (file) – name of the output file

startMine()[source]: Mining process will start from this function