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Write custom chunking algorithms using rxDataStep in RevoScaleR

Important

This content is being retired and may not be updated in the future. The support for Machine Learning Server will end on July 1, 2022. For more information, see What's happening to Machine Learning Server?

Scalability in RevoScaleR is based on chunking or external memory algorithms that can analyze chunks of data in parallel and then combine intermediate results into a single analysis. Because of the chunking algorithms, it's possible to analyze huge datasets that vastly exceed the memory capacity of any one machine.

All of the main analysis functions in RevoScaleR (rxSummary, rxLinMod, rxLogit, rxGlm, rxCube, rxCrossTabs, rxCovCor, rxKmeans, rxDTree, rxBTrees, rxNaiveBayes, and rxDForest) use chunking or external memory algorithms. However, for scenarios where specialized behaviors are needed, you can create a custom chunking algorithms using the rxDataStep function to automatically chunk through your data set and apply arbitrary R functions to process your data.

In this article, you'll step through an example that teaches a simple chunking algorithm for tabulating data implemented using rxDataStep. A more realistic tabulation approach is to use the rxCrossTabs or rxCube functions, but since rxDataStep is simpler, it's a better choice for instruction.

Note

If rxDataStep does not provide sufficient customization, you can build a custom parallel external memory algorithm from the ground up using functions in the RevoPemaR package. For more information, see How to use the RevoPemaR library in Machine Learning Server.

Prerequisites

Sample data for this example is the AirlineDemoSmall.xdf file with a local compute context. For instructions on how to import this data set, see the tutorial in Practice data import and exploration.

Chunking is supported on Machine Learning Server, but not on the free R Client. Because the dataset is small enough to reside in memory on most computers, most systems succeed in running this example locally. however, if the data does not fit in memory, you will need to use Machine Learning Server instead.

About chunking algorithms

An updating algorithm takes a given set of values and a chunk of data, and then outputs a revised set of values cumulative for all chunks. The simplest example is an updating sum: sum is computed for the first chunk, followed by a second chunk, which each successive chunk contributing to a revised value until reaching the cumulative sum.

Updating algorithms perform four main tasks:

  • Initialization: declare and initialize variables needed in the computation.
  • ProcessData: for each block, perform calculations on the data in the block.
  • UpdateResults: combine all of the results of the ProcessData step.
  • ProcessResults: when results from all blocks have been combined, do any final computations.

In this example, no initialization is required.

Example: rxDataStep and sample airline data

The ProcessData step is performed within a transformFunc called by rxDataStep for each chunk of data. In this case we begin with a simple call to the table function after converting the chunk to a data frame. The results are then converted back to a data frame with a single row, which will be appended to a data set on disk. So, the call to rxDataStep reads in the data chunk-by-chunk and creates a new summary data set where each row represents the “intermediate results” of a chunk.

The AggregateResults function shown below combines the UpdateResults and ProcessResults tasks. The summary data set is simply read into memory and the columns are summed.

To try this out, create a new script chunkTable.R with the following contents:

chunkTable <- function(inDataSource, iroDataSource, varsToKeep = NULL,
		blocksPerRead = 1 )
{
	ProcessChunk <- function( dataList)
	{
		# Process Data
		chunkTable <- table(as.data.frame(dataList))
		# Convert table to data frame with single row
		varNames <- names(chunkTable)
			varValues <- as.vector(chunkTable)
			dim(varValues) <- c(1, length(varNames))
			chunkDF <- as.data.frame(varValues)
			names(chunkDF) <- varNames
			# Return the data frame
		return( chunkDF )
	}

	rxDataStep( inData = inDataSource, outFile = iroDataSource,
			varsToKeep = varsToKeep,
		blocksPerRead = blocksPerRead,
		transformFunc = ProcessChunk,
		reportProgress = 0, overwrite = TRUE)

		AggregateResults <- function()    
		{
			iroResults <- rxDataStep(iroDataSource)
			return(colSums(iroResults))
		}

	return(AggregateResults())
}

Note that the blocksPerRead argument is ignored if this script runs locally using R Client. Since Microsoft R Client can only process datasets that fit into the available memory, chunking is not supported in R Client. When run locally with R Client, all data must be read into memory. You can work around this limitation when you push the compute context to a Machine Learning Server instance.

To test the function, use the sample data AirlineDemoSmall.xdf file with a local compute context. For more information, see the tutorial in Practice data import and exploration.

We’ll call our new chunkTable function, processing 1 block at a time so we can take a look at the intermediate results:

	inDataSource <- file.path(rxGetOption("sampleDataDir"),
	    "AirlineDemoSmall.xdf")
	iroDataSource <- "iroFile.xdf"
	chunkOut <- chunkTable(inDataSource = inDataSource,
	    iroDataSource = iroDataSource, varsToKeep="DayOfWeek")
	chunkOut

You will see the following results:

	   Monday   Tuesday Wednesday  Thursday    Friday  Saturday    Sunday
	    97975     77725     78875     81304     82987     86159     94975

To see the intermediate results, we can read the data set into memory:

	rxDataStep(iroDataSource)

	  Monday Tuesday Wednesday Thursday Friday Saturday Sunday
	1  33137   27267     27942    28141  28184    25646  29683
	2  32407   25607     25915    26106  26211    29950  33804
	3  32431   24851     25018    27057  28592    30563  31488

And to delete the intermediate results file:

	file.remove(iroDataSource)

Next steps

This article provides an example of a simple chunking algorithm for tabulating data using rxDataStep.

In practice, you might want to use the rxCrossTabs or rxCube functions. For more information, see rxCrossTabs and rxCube, respectively.

See Also