TestON/JenkinsFile/scripts/SCPFIntentInstallWithdrawRerouteLat.R - OnosSystemTest - Gitiles

 # Copyright 2017 Open Networking Foundation (ONF)
 #
 # Please refer questions to either the onos test mailing list at <onos-test@onosproject.org>,
 # the System Testing Plans and Results wiki page at <https://wiki.onosproject.org/x/voMg>,
 # or the System Testing Guide page at <https://wiki.onosproject.org/x/WYQg>
 #
 #     TestON is free software: you can redistribute it and/or modify
 #     it under the terms of the GNU General Public License as published by
 #     the Free Software Foundation, either version 2 of the License, or
 #     (at your option) any later version.
 #
 #     TestON 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 General Public License for more details.
 #
 #     You should have received a copy of the GNU General Public License
 #     along with TestON.  If not, see <http://www.gnu.org/licenses/>.
 #
 # If you have any questions, or if you don't understand R,
 # please contact Jeremy Ronquillo: jeremyr@opennetworking.org

 # **********************************************************
 # STEP 1: File management.
 # **********************************************************

 print( "STEP 1: File management." )

 # Command line arguments are read. Args usually include the database filename and the output
 # directory for the graphs to save to.
 # ie: Rscript SCPFgraphGenerator SCPFsampleDataDB.csv ~/tmp/
 print( "Reading commmand-line args." )
 args <- commandArgs( trailingOnly=TRUE )

 # Import libraries to be used for graphing and organizing data, respectively.
 # Find out more about ggplot2: https://github.com/tidyverse/ggplot2
 #                     reshape2: https://github.com/hadley/reshape
 print( "Importing libraries." )
 library( ggplot2 )
 library( reshape2 )
 library( RPostgreSQL )    # For databases

 # Check if sufficient args are provided.
 if ( is.na( args[ 9 ] ) ){
     print( "Usage: Rscript SCPFIntentInstallWithdrawRerouteLat.R <isFlowObj> <database-host> <database-port> <database-user-id> <database-password> <test-name> <branch-name> <batch-size> <directory-to-save-graphs>" )
     q()  # basically exit(), but in R
 }

 flowObjFileModifier <- ""
 if ( args[ 1 ] == "y" ){
     flowObjFileModifier <- "fobj_"
 }

 # Filenames for output graphs include the testname and the graph type.
 # See the examples below. paste() is used to concatenate strings.

 errBarOutputFile <- paste( args[ 9 ], "SCPFIntentInstallWithdrawRerouteLat", sep="" )
 errBarOutputFile <- paste( errBarOutputFile, args[ 7 ], sep="_" )
 if ( args[ 1 ] == "y" ){
     errBarOutputFile <- paste( errBarOutputFile, "_fobj", sep="" )
 }
 errBarOutputFile <- paste( errBarOutputFile, "_", sep="" )
 errBarOutputFile <- paste( errBarOutputFile, args[ 8 ], sep="" )
 errBarOutputFile <- paste( errBarOutputFile, "-batchSize", sep="" )
 errBarOutputFile <- paste( errBarOutputFile, "_graph.jpg", sep="" )

 print( "Reading from databases." )

 con <- dbConnect( dbDriver( "PostgreSQL" ), dbname="onostest", host=args[ 2 ], port=strtoi( args[ 3 ] ), user=args[ 4 ],password=args[ 5 ] )

 command1 <- paste( "SELECT * FROM intent_latency_", flowObjFileModifier, sep="" )
 command1 <- paste( command1, "tests WHERE batch_size=", sep="" )
 command1 <- paste( command1, args[ 8 ], sep="" )
 command1 <- paste( command1, " AND branch = '", sep="" )
 command1 <- paste( command1, args[ 7 ], sep="" )
 command1 <- paste( command1, "' AND date IN ( SELECT MAX( date ) FROM intent_latency_", sep="" )
 command1 <- paste( command1, flowObjFileModifier, sep="" )
 command1 <- paste( command1,  "tests WHERE branch='", sep="" )
 command1 <- paste( command1,  args[ 7 ], sep="" )
 command1 <- paste( command1,  "')", sep="" )

 print( paste( "Sending SQL command:", command1 ) )

 fileData1 <- dbGetQuery( con, command1 )

 command2 <- paste( "SELECT * FROM intent_reroute_latency_", flowObjFileModifier, sep="" )
 command2 <- paste( command2, "tests WHERE batch_size=", sep="" )
 command2 <- paste( command2, args[ 8 ], sep="" )
 command2 <- paste( command2, " AND branch = '", sep="" )
 command2 <- paste( command2, args[ 7 ], sep="" )
 command2 <- paste( command2, "' AND date IN ( SELECT MAX( date ) FROM intent_reroute_latency_", sep="" )
 command2 <- paste( command2, flowObjFileModifier, sep="" )
 command2 <- paste( command2,  "tests WHERE branch='", sep="" )
 command2 <- paste( command2,  args[ 7 ], sep="" )
 command2 <- paste( command2,  "')", sep="" )

 print( paste( "Sending SQL command:", command2 ) )

 fileData2 <- dbGetQuery( con, command2 )

 # **********************************************************
 # STEP 2: Organize data.
 # **********************************************************

 print( "STEP 2: Organize data." )

 # Create lists c() and organize data into their corresponding list.
 print( "Sorting data." )
 if ( ncol( fileData2 ) == 0 ){
     avgs <- c( fileData1[ 'install_avg' ], fileData1[ 'withdraw_avg' ] )
 } else{
     colnames( fileData2 ) <- c( "date", "name", "date", "branch", "commit", "scale", "batch_size", "reroute_avg", "reroute_std" )
     avgs <- c( fileData1[ 'install_avg' ], fileData1[ 'withdraw_avg' ], fileData2[ 'reroute_avg' ] )
 }

 # Parse lists into data frames.
 dataFrame <- melt( avgs )              # This is where reshape2 comes in. Avgs list is converted to data frame

 if ( ncol( fileData2 ) == 0 ){
     dataFrame$scale <- c( fileData1$scale, fileData1$scale )      # Add node scaling to the data frame.
     dataFrame$stds <- c( fileData1$install_std, fileData1$withdraw_std )
 } else{
     dataFrame$scale <- c( fileData1$scale, fileData1$scale, fileData2$scale )      # Add node scaling to the data frame.
     dataFrame$stds <- c( fileData1$install_std, fileData1$withdraw_std, fileData2$reroute_std )
 }
 colnames( dataFrame ) <- c( "ms", "type", "scale", "stds" )

 # Format data frame so that the data is in the same order as it appeared in the file.
 dataFrame$type <- as.character( dataFrame$type )
 dataFrame$type <- factor( dataFrame$type, levels=unique( dataFrame$type ) )

 dataFrame <- na.omit( dataFrame )   # Omit any data that doesn't exist

 print( "Data Frame Results:" )
 print( dataFrame )

 # **********************************************************
 # STEP 3: Generate graphs.
 # **********************************************************

 print( "STEP 3: Generate graphs." )

 # 1. Graph fundamental data is generated first.
 #    These are variables that apply to all of the graphs being generated, regardless of type.
 #
 # 2. Type specific graph data is generated.
 #     Data specific for the error bar and stacked bar graphs are generated.
 #
 # 3. Generate and save the graphs.
 #      Graphs are saved to the filename above, in the directory provided in command line args

 print( "Generating fundamental graph data." )

 theme_set( theme_grey( base_size = 20 ) )   # set the default text size of the graph.

 # Calculate window to display graph, based on the lowest and highest points of the data.
 if ( min( dataFrame$ms - dataFrame$stds ) < 0){
     yWindowMin <- min( dataFrame$ms - dataFrame$stds ) * 1.05
 } else {
     yWindowMin <- 0
 }
 yWindowMax <- max( dataFrame$ms + dataFrame$stds )

 mainPlot <- ggplot( data = dataFrame, aes( x = scale, y = ms, ymin = ms - stds, ymax = ms + stds,fill = type ) )

 # Formatting the plot
 width <- 1.3  # Width of the bars.
 xScaleConfig <- scale_x_continuous( breaks=c( 1, 3, 5, 7, 9) )
 yLimit <- ylim( yWindowMin, yWindowMax )
 xLabel <- xlab( "Scale" )
 yLabel <- ylab( "Latency (ms)" )
 fillLabel <- labs( fill="Type" )
 chartTitle <- "Intent Install, Withdraw, & Reroute Latencies"
 if ( args[ 1 ] == "y" ){
     chartTitle <- paste( chartTitle, "w/ FlowObj" )
 }
 chartTitle <- paste( chartTitle, "\nBatch Size =" )
 chartTitle <- paste( chartTitle, fileData1[ 1,'batch_size' ] )

 theme <- theme( plot.title=element_text( hjust = 0.5, size = 22, face='bold' ) )

 # Store plot configurations as 1 variable
 fundamentalGraphData <- mainPlot + xScaleConfig + yLimit + xLabel + yLabel + fillLabel + theme


 # Create the bar graph with error bars.
 # geom_bar contains:
 #    - stat: data formatting (usually "identity")
 #    - width: the width of the bar types (declared above)
 # geom_errorbar contains similar arguments as geom_bar.
 print( "Generating bar graph with error bars." )
 barGraphFormat <- geom_bar( stat = "identity", width = width, position = "dodge" )
 errorBarFormat <- geom_errorbar( width = width, position = "dodge" )
 title <- ggtitle( chartTitle )
 result <- fundamentalGraphData + barGraphFormat + errorBarFormat + title

 # Save graph to file
 print( paste( "Saving bar chart with error bars to", errBarOutputFile ) )
 ggsave( errBarOutputFile, width = 10, height = 6, dpi = 200 )
 print( paste( "Successfully wrote bar chart with error bars out to", errBarOutputFile ) )
	# Copyright 2017 Open Networking Foundation (ONF)
	#
	# Please refer questions to either the onos test mailing list at <onos-test@onosproject.org>,
	# the System Testing Plans and Results wiki page at <https://wiki.onosproject.org/x/voMg>,
	# or the System Testing Guide page at <https://wiki.onosproject.org/x/WYQg>
	#
	# TestON is free software: you can redistribute it and/or modify
	# it under the terms of the GNU General Public License as published by
	# the Free Software Foundation, either version 2 of the License, or
	# (at your option) any later version.
	#
	# TestON 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 General Public License for more details.
	#
	# You should have received a copy of the GNU General Public License
	# along with TestON. If not, see <http://www.gnu.org/licenses/>.
	#
	# If you have any questions, or if you don't understand R,
	# please contact Jeremy Ronquillo: jeremyr@opennetworking.org

	# **********************************************************
	# STEP 1: File management.
	# **********************************************************

	print( "STEP 1: File management." )

	# Command line arguments are read. Args usually include the database filename and the output
	# directory for the graphs to save to.
	# ie: Rscript SCPFgraphGenerator SCPFsampleDataDB.csv ~/tmp/
	print( "Reading commmand-line args." )
	args <- commandArgs( trailingOnly=TRUE )

	# Import libraries to be used for graphing and organizing data, respectively.
	# Find out more about ggplot2: https://github.com/tidyverse/ggplot2
	# reshape2: https://github.com/hadley/reshape
	print( "Importing libraries." )
	library( ggplot2 )
	library( reshape2 )
	library( RPostgreSQL ) # For databases

	# Check if sufficient args are provided.
	if ( is.na( args[ 9 ] ) ){
	print( "Usage: Rscript SCPFIntentInstallWithdrawRerouteLat.R <isFlowObj> <database-host> <database-port> <database-user-id> <database-password> <test-name> <branch-name> <batch-size> <directory-to-save-graphs>" )
	q() # basically exit(), but in R
	}

	flowObjFileModifier <- ""
	if ( args[ 1 ] == "y" ){
	flowObjFileModifier <- "fobj_"
	}

	# Filenames for output graphs include the testname and the graph type.
	# See the examples below. paste() is used to concatenate strings.

	errBarOutputFile <- paste( args[ 9 ], "SCPFIntentInstallWithdrawRerouteLat", sep="" )
	errBarOutputFile <- paste( errBarOutputFile, args[ 7 ], sep="_" )
	if ( args[ 1 ] == "y" ){
	errBarOutputFile <- paste( errBarOutputFile, "_fobj", sep="" )
	}
	errBarOutputFile <- paste( errBarOutputFile, "_", sep="" )
	errBarOutputFile <- paste( errBarOutputFile, args[ 8 ], sep="" )
	errBarOutputFile <- paste( errBarOutputFile, "-batchSize", sep="" )
	errBarOutputFile <- paste( errBarOutputFile, "_graph.jpg", sep="" )

	print( "Reading from databases." )

	con <- dbConnect( dbDriver( "PostgreSQL" ), dbname="onostest", host=args[ 2 ], port=strtoi( args[ 3 ] ), user=args[ 4 ],password=args[ 5 ] )

	command1 <- paste( "SELECT * FROM intent_latency_", flowObjFileModifier, sep="" )
	command1 <- paste( command1, "tests WHERE batch_size=", sep="" )
	command1 <- paste( command1, args[ 8 ], sep="" )
	command1 <- paste( command1, " AND branch = '", sep="" )
	command1 <- paste( command1, args[ 7 ], sep="" )
	command1 <- paste( command1, "' AND date IN ( SELECT MAX( date ) FROM intent_latency_", sep="" )
	command1 <- paste( command1, flowObjFileModifier, sep="" )
	command1 <- paste( command1, "tests WHERE branch='", sep="" )
	command1 <- paste( command1, args[ 7 ], sep="" )
	command1 <- paste( command1, "')", sep="" )

	print( paste( "Sending SQL command:", command1 ) )

	fileData1 <- dbGetQuery( con, command1 )

	command2 <- paste( "SELECT * FROM intent_reroute_latency_", flowObjFileModifier, sep="" )
	command2 <- paste( command2, "tests WHERE batch_size=", sep="" )
	command2 <- paste( command2, args[ 8 ], sep="" )
	command2 <- paste( command2, " AND branch = '", sep="" )
	command2 <- paste( command2, args[ 7 ], sep="" )
	command2 <- paste( command2, "' AND date IN ( SELECT MAX( date ) FROM intent_reroute_latency_", sep="" )
	command2 <- paste( command2, flowObjFileModifier, sep="" )
	command2 <- paste( command2, "tests WHERE branch='", sep="" )
	command2 <- paste( command2, args[ 7 ], sep="" )
	command2 <- paste( command2, "')", sep="" )

	print( paste( "Sending SQL command:", command2 ) )

	fileData2 <- dbGetQuery( con, command2 )

	# **********************************************************
	# STEP 2: Organize data.
	# **********************************************************

	print( "STEP 2: Organize data." )

	# Create lists c() and organize data into their corresponding list.
	print( "Sorting data." )
	if ( ncol( fileData2 ) == 0 ){
	avgs <- c( fileData1[ 'install_avg' ], fileData1[ 'withdraw_avg' ] )
	} else{
	colnames( fileData2 ) <- c( "date", "name", "date", "branch", "commit", "scale", "batch_size", "reroute_avg", "reroute_std" )
	avgs <- c( fileData1[ 'install_avg' ], fileData1[ 'withdraw_avg' ], fileData2[ 'reroute_avg' ] )
	}

	# Parse lists into data frames.
	dataFrame <- melt( avgs ) # This is where reshape2 comes in. Avgs list is converted to data frame

	if ( ncol( fileData2 ) == 0 ){
	dataFrame$scale <- c( fileData1$scale, fileData1$scale ) # Add node scaling to the data frame.
	dataFrame$stds <- c( fileData1$install_std, fileData1$withdraw_std )
	} else{
	dataFrame$scale <- c( fileData1$scale, fileData1$scale, fileData2$scale ) # Add node scaling to the data frame.
	dataFrame$stds <- c( fileData1$install_std, fileData1$withdraw_std, fileData2$reroute_std )
	}
	colnames( dataFrame ) <- c( "ms", "type", "scale", "stds" )

	# Format data frame so that the data is in the same order as it appeared in the file.
	dataFrame$type <- as.character( dataFrame$type )
	dataFrame$type <- factor( dataFrame$type, levels=unique( dataFrame$type ) )

	dataFrame <- na.omit( dataFrame ) # Omit any data that doesn't exist

	print( "Data Frame Results:" )
	print( dataFrame )

	# **********************************************************
	# STEP 3: Generate graphs.
	# **********************************************************

	print( "STEP 3: Generate graphs." )

	# 1. Graph fundamental data is generated first.
	# These are variables that apply to all of the graphs being generated, regardless of type.
	#
	# 2. Type specific graph data is generated.
	# Data specific for the error bar and stacked bar graphs are generated.
	#
	# 3. Generate and save the graphs.
	# Graphs are saved to the filename above, in the directory provided in command line args

	print( "Generating fundamental graph data." )

	theme_set( theme_grey( base_size = 20 ) ) # set the default text size of the graph.

	# Calculate window to display graph, based on the lowest and highest points of the data.
	if ( min( dataFrame$ms - dataFrame$stds ) < 0){
	yWindowMin <- min( dataFrame$ms - dataFrame$stds ) * 1.05
	} else {
	yWindowMin <- 0
	}
	yWindowMax <- max( dataFrame$ms + dataFrame$stds )

	mainPlot <- ggplot( data = dataFrame, aes( x = scale, y = ms, ymin = ms - stds, ymax = ms + stds,fill = type ) )

	# Formatting the plot
	width <- 1.3 # Width of the bars.
	xScaleConfig <- scale_x_continuous( breaks=c( 1, 3, 5, 7, 9) )
	yLimit <- ylim( yWindowMin, yWindowMax )
	xLabel <- xlab( "Scale" )
	yLabel <- ylab( "Latency (ms)" )
	fillLabel <- labs( fill="Type" )
	chartTitle <- "Intent Install, Withdraw, & Reroute Latencies"
	if ( args[ 1 ] == "y" ){
	chartTitle <- paste( chartTitle, "w/ FlowObj" )
	}
	chartTitle <- paste( chartTitle, "\nBatch Size =" )
	chartTitle <- paste( chartTitle, fileData1[ 1,'batch_size' ] )

	theme <- theme( plot.title=element_text( hjust = 0.5, size = 22, face='bold' ) )

	# Store plot configurations as 1 variable
	fundamentalGraphData <- mainPlot + xScaleConfig + yLimit + xLabel + yLabel + fillLabel + theme


	# Create the bar graph with error bars.
	# geom_bar contains:
	# - stat: data formatting (usually "identity")
	# - width: the width of the bar types (declared above)
	# geom_errorbar contains similar arguments as geom_bar.
	print( "Generating bar graph with error bars." )
	barGraphFormat <- geom_bar( stat = "identity", width = width, position = "dodge" )
	errorBarFormat <- geom_errorbar( width = width, position = "dodge" )
	title <- ggtitle( chartTitle )
	result <- fundamentalGraphData + barGraphFormat + errorBarFormat + title

	# Save graph to file
	print( paste( "Saving bar chart with error bars to", errBarOutputFile ) )
	ggsave( errBarOutputFile, width = 10, height = 6, dpi = 200 )
	print( paste( "Successfully wrote bar chart with error bars out to", errBarOutputFile ) )