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Syntax conformation

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This commit is contained in:
Craig Williams
2019-04-11 12:47:53 +01:00
parent 7752b73bc6
commit 29e0bd0cf2
2 changed files with 325 additions and 297 deletions
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237
Parses.R
View File

@@ -1,27 +1,27 @@
modules::import(openxlsx)
modules::import(bnlearn)
modules::import(openxlsx)
modules::import(stringr)
modules::import(graph)
modules::import(ggplot2)
modules::import(stats)
modules::import(plotly)
modules::import(utils)
#Improvements needed: make the selection of first row/column of nodes programmatic
FIRST_NODE_COL <- 3
mappings <- c('TestScenario', 'Map_P_BA', 'Map_BA_OP', 'Map_OP_ES')
nodeTypes <- c('Input.Nodes', 'Internal.Nodes', 'Published.Nodes')
states <- c('impact', 'confidence', 'growth', 'recovery', 'layer')
refs <-c(1:length(mappings))
mappings <- c("TestScenario", "Map_P_BA", "Map_BA_OP", "Map_OP_ES")
nodeTypes <- c("Input.Nodes", "Internal.Nodes", "Published.Nodes")
states <- c("impact", "confidence", "growth", "recovery", "layer")
refs <- c(1:length(mappings))
setEmpties <- function(val) {
if (is.na(val)) return(0) else return(val)
if (is.na(val)) {
return(0)
} else {
return(val)
}
}
readXL <- function(fName, sheetN, startRow=1) {
readXL <- function(fName, sheetN, startRow = 1) {
xl <- read.xlsx(fName, sheet = sheetN, startRow) #, rowNames = import)
return(data.frame(xl, stringsAsFactors = FALSE, row.names = NULL))
}
@@ -32,73 +32,87 @@ delNA <- function(vec) {
buildExpr <- function(pressStatus) {
#pressStatus is a two column DF of name of pressure and status Ii.e. on or off)
MEANPRESS = 0
MEANPRESS <- 0
expr <- "("
for (p in 1:nrow(pressStatus)) {
if (pressStatus$status[p] == 'On') symbol='>=' else symbol='<='
if (pressStatus$status[p] == "On") {
symbol <- ">="
} else {
symbol <- "<="
}
expr <- paste0(expr, "(\"", pressStatus$code[p], "\"", symbol, MEANPRESS, ") & ")
}
expr<-substr(expr, 1, nchar(expr)-2)
expr<-paste0(expr, ')')
expr <- substr(expr, 1, nchar(expr) - 2)
expr <- paste0(expr, ")")
return(expr)
}
parseScenario <- function(press, prefix = 'p') {
parseScenario <- function(press, prefix = "p") {
pressNames <- colnames(press)[2:length(colnames(press))]
coefs <- matrix(data=NA, nrow=length(pressNames), ncol=3, dimnames=list(NULL, c('growth', 'confidence', 'layer')))
coefs <- matrix(
data = NA,
nrow = length(pressNames),
ncol = 3,
dimnames = list(NULL, c("growth", "confidence", "layer"))
)
for (col in 2:ncol(press)) {
coefs[col-1,] <- as.numeric(split(press[1, col]))[match(c('growth', 'confidence', 'layer'), states)]
coefs[col-1,] <- as.numeric(split(press[1, col]))[match(c("growth", "confidence", "layer"), states)]
}
press[is.na(press)] <- 0
if (sum(duplicated(pressNames))>0) {
cat('Duplicated pressure node names found')
if (sum(duplicated(pressNames)) > 0) {
cat("Duplicated pressure node names found")
print(pressNodes[duplicated(pressNames)])
}
return(list(
timeSeq=press,
nodes=data.frame(name = pressNames,
code=paste0(prefix, seq(1:length(pressNames))),
growth = coefs[,'growth'],
confidence=coefs[,'confidence'],
layer=coefs[,'layer'],
stringsAsFactors = FALSE),
edges=data.frame(input=NULL, output=NULL, impact=NULL)
timeSeq = press,
nodes = data.frame(
name = pressNames,
code = paste0(prefix, seq(1:length(pressNames))),
growth = coefs[,"growth"],
confidence = coefs[,"confidence"],
layer = coefs[,"layer"],
stringsAsFactors = FALSE
),
edges = data.frame(input = NULL, output = NULL, impact = NULL)
))
}
getInitial <- function(string, letter) {
return(tolower(substr(string, start=1, stop=1)))
return(tolower(substr(string, start = 1, stop = 1)))
}
split <- function(cell) {
params <- unlist(strsplit(cell, ','))
params <- unlist(strsplit(cell, ","))
values <- rep(0, length(states))
for (n in 1:length(params)) {
kvp <- unlist(strsplit(params[n], '='))
kvp <- unlist(strsplit(params[n], "="))
ref <- match(getInitial(trimws(kvp[1])), getInitial(states))
if ((ref>0) & (ref<=length(values))) {
if ((ref > 0) & (ref <= length(values))) {
values[ref] <- kvp[2]
} else {
print(paste('Unrecognised parameter(s):',params[n]))
print(paste("Unrecognised parameter(s):",params[n]))
}
}
}
return(values)
}
cleanTitles <- function(titleV) {
return(str_replace_all(titleV, c(' ' = '.', '-' = '')))
return(str_replace_all(titleV, c(" " = ".", "-" = "")))
}
getOutNodes <- function(codes, codeList) {
v <- vector(mode='logical', length=length(codes))
v <- vector(mode = "logical", length = length(codes))
for (idx in 1:length(codes)) {
v[idx] <- (sum(startsWith(codes[idx], codeList))>0)
v[idx] <- (sum(startsWith(codes[idx], codeList)) > 0)
}
return(v)
}
@@ -112,38 +126,38 @@ buildGraph <- function(model, desc) {
#outputCodes - all subsequent layers to be included in the model
inputNodes <- model$nodes$code[which(startsWith(model$nodes$code, desc$inputCode))]
inputText <- paste0("[", inputNodes, "]", collapse ="")
inputText <- paste0("[", inputNodes, "]", collapse = "")
#do the internal nodes
edges <- ""
outNodes <- model$nodes$code[getOutNodes(model$nodes$code, desc$outputCodes)]
outDist <- vector(mode="list", length=length(outNodes))
outDist <- vector(mode = "list", length = length(outNodes))
for (idx in 1:length(outNodes)) {
nodeRef <- match(outNodes[idx], model$nodes$code)
rows <- which(model$edges$output == outNodes[idx])
inputsStr <- paste0(model$edges$input[which(model$edges$output == outNodes[idx])], sep=":", collapse="")
edges <- paste0(edges, paste0("[", outNodes[idx], "|", substr(inputsStr, start=1, stop=(nchar(inputsStr)-1)), "]"))
inputsStr <- paste0(model$edges$input[which(model$edges$output == outNodes[idx])], sep = ":", collapse = "")
edges <- paste0(edges, paste0("[", outNodes[idx], "|", substr(inputsStr, start = 1, stop = (nchar(inputsStr)-1)), "]"))
#Make the coefficient of the distribution
coefVal <- setNames(c(model$nodes$growth[nodeRef], model$edges$values[rows]),
coefVal <- setNames(
c(model$nodes$growth[nodeRef], model$edges$values[rows]),
c("(Intercept)", model$edges$input[rows])
)
#str(coefVal)
outDist[[idx]] <- list(coef = coefVal,
sd = model$nodes$confidence[nodeRef])
outDist[[idx]] <- list(coef = coefVal, sd = model$nodes$confidence[nodeRef])
}
print('about to build network')
print("about to build network")
print(paste0(inputText, edges))
net <- model2network(paste0(inputText, edges), debug=TRUE)
net <- model2network(paste0(inputText, edges), debug = TRUE)
print('network build successful')
print("network build successful")
inDist <- vector(mode="list", length=length(inputNodes))
inDist <- vector(mode = "list", length = length(inputNodes))
for (idx in 1:length(inputNodes)) {
inRef <- match(inputNodes[idx], model$nodes$code)
@@ -151,17 +165,17 @@ buildGraph <- function(model, desc) {
inDist[[idx]] <- list(coef = coefVal, sd = model$nodes$confidence[inRef])
}
allDists = as.list(setNames(c(inDist, outDist), c(inputNodes, outNodes)))
cfit = custom.fit(net, allDists)
allDists <- as.list(setNames(c(inDist, outDist), c(inputNodes, outNodes)))
cfit <- custom.fit(net, allDists)
cat('about to calculate sample distributions')
cat("about to calculate sample distributions")
print(outNodes)
sampleDists <- cpdist(cfit, nodes = outNodes, evidence = TRUE, n = 10000, method = "lw")
summDists <- summary(sampleDists)
#stdDev <- sd(sampleDists)
print('sample distribution build successful')
print("sample distribution build successful")
model$edges$input <- model$nodes$name[match(model$edges$input, model$nodes$code)]
model$edges$output <- model$nodes$name[match(model$edges$output, model$nodes$code)]
@@ -185,58 +199,62 @@ getValidNodes <- function(mapping, prevOutputs, prefix) {
inputNodes <- mapping[2:nrow(mapping),1]
#check that all input nodes are in the previous table
inputNodes <- delNA(mapping[mapping[,"Node.Type"] == 'input', "Nodes"])
if (length(inputNodes)>0) {
if (sum(inputNodes %in% prevOutputs$name)<length(inputNodes)) {
cat('Missing entries for input nodes in previous output columns')
inputNodes <- delNA(mapping[mapping[,"Node.Type"] == "input", "Nodes"])
if (length(inputNodes) > 0) {
if (sum(inputNodes %in% prevOutputs$name) < length(inputNodes)) {
cat("Missing entries for input nodes in previous output columns")
print(inputNodes[!inputNodes %in% prevOutputs$name])
}
} else print('Invalid sheet - table must have at least one input row containing names from previous table')
} else {
print("Invalid sheet - table must have at least one input row containing names from previous table")
}
#Check the row headings concur with previous names
validInputs <- delNA(inputNodes[which(unique(inputNodes) %in% prevOutputs$name)])
if (length(validInputs)==0) print('Invalid sheet - table must have at least one input row containing names from previous table')
if (length(validInputs) == 0) {
print("Invalid sheet - table must have at least one input row containing names from previous table")
}
inputInts <- delNA(inputNodes[mapping$Node.Type!='link'])
inputInts <- delNA(inputNodes[mapping$Node.Type != "link"])
if (sum(duplicated(inputInts))>0) {
cat('Duplicated input node names found')
cat("Duplicated input node names found")
print(inputNodes[duplicated(inputNodes)])
}
outNodes <- delNA(colnames(mapping)[FIRST_NODE_COL:ncol(mapping)])
if (sum(duplicated(outNodes))>0) {
cat('Duplicated output node names found')
if (sum(duplicated(outNodes)) > 0) {
cat("Duplicated output node names found")
print(outNodes[duplicated(outNodes)])
}
#check that all internal nodes are in the columns
intNodes <- delNA(mapping[mapping[,"Node.Type"] == 'internal', "Nodes"])
if (length(intNodes)>0) {
intNodes <- delNA(mapping[mapping[,"Node.Type"] == "internal", "Nodes"])
if (length(intNodes) > 0) {
if (sum(intNodes %in% outNodes)<length(intNodes)) {
cat('Missing entries for internal nodes in output columns')
print(intNodes[!intNodes %in% outNodes])
cat("Missing entries for internal nodes in output columns")
print(intNodes[!(intNodes %in% outNodes)])
}
}
coefs <- matrix(data=NA, nrow=length(outNodes), ncol=3, dimnames=list(NULL, c('growth', 'confidence', 'layer')))
coefs <- matrix(data = NA, nrow = length(outNodes), ncol = 3, dimnames = list(NULL, c("growth", "confidence", "layer")))
for (idx in 1:length(outNodes)) {
col <- match(outNodes[idx], colnames(mapping))
coefs[idx,] <- as.numeric(split(mapping[1, col]))[match(c('growth', 'confidence', 'layer'), states)]
coefs[idx,] <- as.numeric(split(mapping[1, col]))[match(c("growth", "confidence", "layer"), states)]
}
print(coefs)
return(data.frame(
code=c(prevOutputs$code, paste0(prefix, seq(1:length(outNodes)))),
name=c(prevOutputs$name, outNodes),
growth=c(prevOutputs$growth, coefs[,"growth"]),
confidence=c(prevOutputs$confidence, coefs[,"confidence"]),
layer=c(prevOutputs$layer, coefs[,"layer"]),
stringsAsFactors=FALSE
code = c(prevOutputs$code, paste0(prefix, seq(1:length(outNodes)))),
name = c(prevOutputs$name, outNodes),
growth = c(prevOutputs$growth, coefs[,"growth"]),
confidence = c(prevOutputs$confidence, coefs[,"confidence"]),
layer = c(prevOutputs$layer, coefs[,"layer"]),
stringsAsFactors = FALSE
))
}
@@ -244,14 +262,15 @@ getCode <- function(name, nodeDF) {
nodeDF$code[match(name, nodeDF$name)]
}
getValidEdges <- function(mapping, nodeDF, prevEdge=NULL, prefix) {
str(nodeDF)
edgeCols <- c('inputNode', 'outputNode', 'impact')
edgeM <- matrix(data=NA, nrow=0, ncol=length(edgeCols), dimnames=list(NULL, edgeCols))
getValidEdges <- function(mapping, nodeDF, prevEdge = NULL, prefix) {
utils::str(nodeDF)
edgeCols <- c("inputNode", "outputNode", "impact")
edgeM <- matrix(data = NA, nrow = 0, ncol = length(edgeCols), dimnames = list(NULL, edgeCols))
#to start let just get the statements and print them out....
for (col in FIRST_NODE_COL:ncol(mapping)) {
count=0
count <- 0
for (row in 2:nrow(mapping)) {
@@ -259,76 +278,74 @@ getValidEdges <- function(mapping, nodeDF, prevEdge=NULL, prefix) {
edgeM <- rbind(edgeM,
c(getCode(mapping[row, 1], nodeDF),
getCode(colnames(mapping)[col], nodeDF),
split(mapping[row,col])[match('impact', states)]
split(mapping[row,col])[match("impact", states)]
)
)
count=count+1
count <- count + 1
}
#if (count==0) print(paste('No edges found for output', colnames(mapping)[col]))
#if (count == 0) print(paste("No edges found for output", colnames(mapping)[col]))
}
}
if (is.null(prevEdge)) return (
data.frame(
if (is.null(prevEdge)) {
return (data.frame(
input = edgeM[,"inputNode"],
output = edgeM[,"outputNode"],
impact = edgeM[,"impact"],
stringsAsFactors = FALSE
)
) else return (
data.frame(
))
} else {
return (data.frame(
input = c(prevEdge$input, edgeM[,"inputNode"]),
output = c(prevEdge$output, edgeM[,"outputNode"]),
impact = c(prevEdge$impact, edgeM[,"impact"]),
stringsAsFactors = FALSE
)
)
))
}
}
parseMapping <- function(mapping, prevOutputs, prefix) {
mapping <- mapping[,-1]
mapping[,1] <- cleanTitles(mapping[,1])
nodeDF <- getValidNodes(mapping, prevOutputs$nodes, prefix)
edgeDF <- getValidEdges(mapping, nodeDF, prevEdge=prevOutputs$edges, prefix)
edgeDF <- getValidEdges(mapping, nodeDF, prevEdge = prevOutputs$edges, prefix)
return(list(
#New structure
nodes=nodeDF,
edges=edgeDF
nodes = nodeDF,
edges = edgeDF
))
}
parseSheet <- function(fName) {
#get sheet names
print(paste('starting sheet load', fName))
print(paste("starting sheet load", fName))
if (file.exists(fName)) {
names <- openxlsx::getSheetNames(fName)
if (length(names)>0) {
if (length(names) > 0) {
sheets <- sort(delNA(match(names, mappings)))
cat('starting sheet parse')
cat("starting sheet parse")
print(sheets)
if (sum(sheets==refs)==length(refs)) {
if (sum(sheets == refs) == length(refs)) {
#read all mapping tables
scenario <- parseScenario(readXL(fName,mappings[1], startRow=1), prefix='p')
p_ba <- parseMapping(readXL(fName,mappings[2], startRow=1), scenario, prefix='ba')
p_op <- parseMapping(readXL(fName,mappings[3], startRow=1), p_ba, prefix='op')
p_es <- parseMapping(readXL(fName,mappings[4], startRow=1), p_op, prefix='es')
scenario <- parseScenario(readXL(fName,mappings[1], startRow = 1), prefix = "p")
p_ba <- parseMapping(readXL(fName,mappings[2], startRow = 1), scenario, prefix = "ba")
p_op <- parseMapping(readXL(fName,mappings[3], startRow = 1), p_ba, prefix = "op")
p_es <- parseMapping(readXL(fName,mappings[4], startRow = 1), p_op, prefix = "es")
#print('building graphs')
#print("building graphs")
#p_baNet <- buildGraph(p_ba, desc=list(inputCode='p', outputCodes='ba'))
#p_opNet <- buildGraph(p_op, desc=list(inputCode='p', outputCodes=c('ba', 'op')))
#p_esNet <- buildGraph(p_es, desc=list(inputCode='p', outputCodes=c('ba', 'op', 'es')))
#p_baNet <- buildGraph(p_ba, desc = list(inputCode = "p", outputCodes = "ba"))
#p_opNet <- buildGraph(p_op, desc = list(inputCode = "p", outputCodes = c("ba", "op")))
#p_esNet <- buildGraph(p_es, desc = list(inputCode = "p", outputCodes = c("ba", "op", "es")))
print('sheet load completed')
print("sheet load completed")
return(
#list(
#pressBioAss = p_baNet,
@@ -339,8 +356,8 @@ parseSheet <- function(fName) {
)
} else {
print(paste('Sheets found include', mappings[sheets]))
cat('Missing sheets are:')
print(paste("Sheets found include", mappings[sheets]))
cat("Missing sheets are:")
print(refs[-sheets])
}
}

351
app.R
View File

@@ -1,47 +1,40 @@
modules::import(DT)
modules::import(shiny)
modules::import(shinyBS)
modules::import(shinyjs)
modules::import(shinydashboard)
modules::import(shinydashboardPlus)
modules::import(htmltools)
modules::import(DiagrammeR)
modules::import(magrittr)
modules::import(plotly)
modules::import(kableExtra)
modules::import(Rgraphviz)
modules::import(knitr)
modules::import(shinycssloaders)
modules::import(googleway)
modules::import(shinyjs)
modules::import(bnlearn)
modules::import(visNetwork)
modules::import(RColorBrewer)
modules::import(zip)
modules::import(processx)
modules::import(plotly)
modules::import(openxlsx)
modules::import(zip)
modules::import(DT)
parser <- modules::use("Parses.R")
parser <- modules::use('Parses.R')
layers <- c("Pressures to Bio-Assemblages", "Bio-Assemblages to Output Processes", "Output Processes to Ecosystem services")
transitions <- c("Pressures to Bio-Assemblages", "Pressures to Output Processes", "Pressures to Ecosystem services")
impacts <- c('Very High', '>=High', '>=Medium', '>=Low', 'All')
thresholds <- c(0.97, 0.9, 0.45, 0.17, 0)
impLabels <- c('Very High', 'High', 'Medium', 'Low', 'Very Low')
legends <- c('Pressures',
'Suspension feeders',
'Mobile and burrow dwellers',
'Predators',
'Epifauna and algae',
'Functional groups',
'Output processes',
'Output enablers',
'Ecosystem services')
addResourcePath("js", "./www/js")
ui<-dashboardPage(
layers <- c("Pressures to Bio-Assemblages", "Bio-Assemblages to Output Processes", "Output Processes to Ecosystem services")
transitions <- c("Pressures to Bio-Assemblages", "Pressures to Output Processes", "Pressures to Ecosystem services")
impacts <- c("Very High", ">= High", ">= Medium", ">= Low", "All")
thresholds <- c(0.97, 0.9, 0.45, 0.17, 0)
impLabels <- c("Very High", "High", "Medium", "Low", "Very Low")
legends <- c("Pressures",
"Suspension feeders",
"Mobile and burrow dwellers",
"Predators",
"Epifauna and algae",
"Functional groups",
"Output processes",
"Output enablers",
"Ecosystem services")
ui <- dashboardPage(
dashboardHeader(title = "JNCC MESO online",
tags$li(
id = "dropdownHelp",
@@ -95,52 +88,52 @@ ui<-dashboardPage(
menuItem("Bayesian Network", tabName = "2", icon = icon("atom")),
#menuItem("Habitats", tabName = "3", icon = icon("atlas")),
#menuItem("Ingestion", tabName = "3", icon = icon("utensils")),
selectInput("modelSelect", "Select MESO model", choices=c(""), selected=NULL, multiple=FALSE),
downloadButton("download", "", icon=icon("download")),
selectInput("modelSelect", "Select MESO model", choices = c(""), selected = NULL, multiple = FALSE),
downloadButton("download", "", icon = icon("download")),
uiOutput("pressureList")
#selectInput("layerSelect", "Select Transition",
# choices=transitions,
# selected=NULL, multiple=FALSE)
# choices = transitions,
# selected = NULL, multiple = FALSE)
)
),
dashboardBody(
tabItems(
tabItem(tabName = "1", h2('Impact Distribution'),
tabItem(tabName = "1", h2("Impact Distribution"),
fluidRow(
column(
width=6,
h4('Effect on bio-assemblage')
width = 6,
h4("Effect on bio-assemblage")
),
column(
width=1,
actionButton("layer1Slider", "1", icon=icon("sliders-h"))
width = 1,
actionButton("layer1Slider", "1", icon = icon("sliders-h"))
),
column(
width=5,
width = 5,
strong("Customise sensitivity weightings")
)
),
plotlyOutput("layer1", height="270px") %>% withSpinner(),
h4('Effect on Output Processes'),
plotlyOutput("layer2", height="270px") %>% withSpinner(),
h4('Effect on Ecosystem services'),
plotlyOutput("layer3", height="270px") %>% withSpinner()
plotlyOutput("layer1", height = "270px") %>% withSpinner(),
h4("Effect on Output Processes"),
plotlyOutput("layer2", height = "270px") %>% withSpinner(),
h4("Effect on Ecosystem services"),
plotlyOutput("layer3", height = "270px") %>% withSpinner()
),
tabItem(tabName = "2",h2("Bayesian Network"),
fluidPage(
p('Graphical output of the Bayesian Network. Note: The graph will only draw if pressures are applied!'),
p("Graphical output of the Bayesian Network. Note: The graph will only draw if pressures are applied!"),
fluidRow(
column(
width=4,
checkboxInput("bbnDisplayNames", "Display Node names", value=FALSE)
width = 4,
checkboxInput("bbnDisplayNames", "Display Node names", value = FALSE)
),
column(
width=4,
checkboxInput("bbnDisplayEdges", "Display edge status", value=FALSE)
width = 4,
checkboxInput("bbnDisplayEdges", "Display edge status", value = FALSE)
),
column(
width=4,
selectInput("bbnImpactSelect", "Impact Threshold", choices=impacts, selected='All')
width = 4,
selectInput("bbnImpactSelect", "Impact Threshold", choices = impacts, selected = "All")
)
),
fluidRow(
@@ -148,14 +141,14 @@ ui<-dashboardPage(
),
fluidRow(
column(
width=6,
h4('Ecoservice nodes'),
DT::dataTableOutput('nodeTable')
width = 6,
h4("Ecoservice nodes"),
DT::dataTableOutput("nodeTable")
),
column(
width=6,
h4('Ecoservice influences'),
DT::dataTableOutput('edgeTable')
width = 6,
h4("Ecoservice influences"),
DT::dataTableOutput("edgeTable")
)
)
)
@@ -169,8 +162,8 @@ ui<-dashboardPage(
fluidPage(
p("Select a spreadsheet from your network for input into the JNCC Bayesian Network Analyser:"),
fileInput("fileSelect", "Choose Excel Spreadsheet File (xlsx format)", multiple = FALSE, accept = "xlsx"),
fluidRow(renderUI('status')),
actionButton('loadAB', 'Load') # icon='upload')
fluidRow(renderUI("status")),
actionButton("loadAB", "Load") # icon = "upload")
)
)
)
@@ -180,20 +173,20 @@ ui<-dashboardPage(
server <- function(input, output, session) {
#SERVER Constants
print('Loading data')
print("Loading data")
#set_key("AIzaSyAw8_btgGN1drf8qhCxNcotP6r11qEXA_M")
dataStorage <- 'data/'
dataStorage <- "data/"
models<-NULL
models <- NULL
pressures <- NULL
.loadStatus <- reactiveValues(
valid = c(p=FALSE, ba=FALSE, op=FALSE, es=FALSE),
valid = c(p = FALSE, ba = FALSE, op = FALSE, es = FALSE),
msgs = NULL
)
.likelihoods <-reactiveValues(
.likelihoods <- reactiveValues(
p_ba = NULL,
ba_os = NULL,
os_es = NULL,
@@ -206,7 +199,7 @@ server <- function(input, output, session) {
.resistanceScores <- c(
ins= -0.01,
ins = -0.01,
hr = -0.2,
mr = -0.75,
lr = -0.95,
@@ -216,11 +209,11 @@ server <- function(input, output, session) {
)
.selections <- reactiveValues(
model=1,
bbnImpact=1,
bbnNames=FALSE,
bbnEdges=FALSE,
pressStatus=NULL
model = 1,
bbnImpact = 1,
bbnNames = FALSE,
bbnEdges = FALSE,
pressStatus = NULL
)
getImpact <- function(v) {
@@ -234,13 +227,13 @@ server <- function(input, output, session) {
}
getAvailableModels <- function() {
fileList <- list.files(dataStorage, pattern='.xlsx')
fileList <- list.files(dataStorage, pattern = ".xlsx")
modelList <- list()
cnt<-1
cnt <- 1
for (idx in 1:length(fileList)) {
print(paste('attempting to load', paste0(dataStorage, fileList[idx])))
print(paste("attempting to load", paste0(dataStorage, fileList[idx])))
tmp <- parser$parseSheet(paste0(dataStorage, fileList[idx]))
print(tmp)
@@ -249,12 +242,12 @@ server <- function(input, output, session) {
if (!is.null(tmp)) {
modelList[[cnt]] <- tmp
models <<- c(models, substr(fileList[idx], 1, (nchar(fileList[idx])-5)))
print(paste('Model file successfully loaded', fileList[idx]))
#save(tmp, file='tmp.RData')
cnt=cnt+1
print(paste("Model file successfully loaded", fileList[idx]))
#save(tmp, file = "tmp.RData")
cnt <- cnt+1
}
}
updateSelectInput(session, "modelSelect", choices=models)
updateSelectInput(session, "modelSelect", choices = models)
return(modelList)
}
@@ -266,41 +259,41 @@ server <- function(input, output, session) {
isolate({
#if (layer==1) layerStr='ba' else if (layer==2) layerStr='op' else if (layer==3) layerStr='es'
#if (layer == 1) layerStr = "ba" else if (layer == 2) layerStr = "op" else if (layer == 3) layerStr = "es"
#layerRange <- which(startsWith(thisModel$nodes$code, layerStr))
#nodeCodes <-thisModel$nodes$code[layerRange]
#nodeCodes <- thisModel$nodes$code[layerRange]
#nodeNames <- thisModel$nodes$name[layerRange]
thisModel <- modelList[[.selections$model]]
modelList[[.selections$model]]$edges$values <<- sapply(thisModel$edges$impact, getImpact)
modelList[[.selections$model]]$nodes$growth <<- .resistanceScores['ssgr']
modelList[[.selections$model]]$nodes$confidence <<- .resistanceScores['pressSD']
modelList[[.selections$model]]$nodes$growth <<- .resistanceScores["ssgr"]
modelList[[.selections$model]]$nodes$confidence <<- .resistanceScores["pressSD"]
thisModel <- modelList[[.selections$model]]
MEANPOS=1
MEANNEG=0
MEANPOS <- 1
MEANNEG <- 0
expr <- "list("
for (p in 1:nrow(pressStatus)) {
if (pressStatus$status[p] == 'On') {
threshold = MEANPOS
if (pressStatus$status[p] == "On") {
threshold <- MEANPOS
} else {
threshold = MEANNEG
threshold <- MEANNEG
}
expr <- paste0(expr, "\"", pressStatus$code[p], "\"=", threshold, ", ")
expr <- paste0(expr, "\"", pressStatus$code[p], "\" = ", threshold, ", ")
}
expr <-substr(expr, 1, nchar(expr)-2)
expr<-paste0(expr, ')')
expr <- substr(expr, 1, nchar(expr)-2)
expr <- paste0(expr, ")")
thisNet <- parser$buildGraph(thisModel, desc=list(inputCode='p', outputCodes=c('ba', 'op', 'es')))
thisNet <- parser$buildGraph(thisModel, desc = list(inputCode = "p", outputCodes = c("ba", "op", "es")))
sampleDists <- cpdist(
fitted = thisNet$cfit,
@@ -308,7 +301,7 @@ server <- function(input, output, session) {
evidence = eval(parse(text = expr)),
method = "lw",
n = 10000,
debug=TRUE
debug = TRUE
)
})
@@ -319,7 +312,7 @@ server <- function(input, output, session) {
means <- apply(sampleDists, 2, mean)
stdDev <- apply(sampleDists, 2, sd)
print(paste('Building likelihoods from model, sample dists', length(thisModel$nodes$name), length(sampleDists)))
print(paste("Building likelihoods from model, sample dists", length(thisModel$nodes$name), length(sampleDists)))
return(data.frame(
name = thisModel$nodes$name,
@@ -334,7 +327,7 @@ server <- function(input, output, session) {
means + 2*stdDev,
apply(sampleDists, 2, max)
),
stringsAsFactors=FALSE
stringsAsFactors = FALSE
))
}
@@ -347,19 +340,21 @@ server <- function(input, output, session) {
isolate(myList <- reactiveValuesToList(input))
matches <- match(pressures$code, names(myList))
if (length(matches)>0) {
status <-NULL
for (n in 1:length(matches)) status[n] = myList[[matches[n]]]
if (length(matches) > 0) {
status <- NULL
for (n in 1:length(matches)) {
status[n] <- myList[[matches[n]]]
}
newStatus <- data.frame(code=pressures$code, status=status, stringsAsFactors = FALSE)
newStatus <- data.frame(code = pressures$code, status = status, stringsAsFactors = FALSE)
if (!identical(newStatus, .selections$pressStatus)) {
print('Running calc')
print("Running calc")
#.likelihoods$p_ba <<- calcLikelihood(1, newStatus)
#.likelihoods$ba_os <<- calcLikelihood(2, newStatus)
#.likelihoods$os_es <<- calcLikelihood(3, newStatus)
.likelihoods$p_es <<- calcLikelihood(0, newStatus)
#write.xlsx(.likelihoods$p_es, 'tmp.xlsx')
#write.xlsx(.likelihoods$p_es, "tmp.xlsx")
.selections$pressStatus <<- newStatus
}
@@ -367,15 +362,18 @@ server <- function(input, output, session) {
})
makeRadioButtons <- function(row) {
radioButtons(row['code'], row['name'], choices=c('Off', 'On'), selected='Off', inline=TRUE)
radioButtons(row["code"], row["name"], choices = c("Off", "On"), selected = "Off", inline = TRUE)
}
output$pressureList <- renderUI({
#isolate({
if (!is.null(modelList[[.selections$model]]$nodes)) {
pressCodes <- which(startsWith(modelList[[.selections$model]]$nodes$code, 'p'))
pressures <- data.frame(code = modelList[[.selections$model]]$nodes$code[pressCodes],
name = modelList[[.selections$model]]$nodes$name[pressCodes], stringsAsFactors=FALSE)
pressCodes <- which(startsWith(modelList[[.selections$model]]$nodes$code, "p"))
pressures <- data.frame(
code = modelList[[.selections$model]]$nodes$code[pressCodes],
name = modelList[[.selections$model]]$nodes$name[pressCodes],
stringsAsFactors = FALSE
)
setPressures(pressures)
btnList <- apply(pressures, 1, makeRadioButtons)
}
@@ -402,36 +400,36 @@ server <- function(input, output, session) {
showModal(
modalDialog({
tagList(
sliderInput("l1VL", "Insensitive", 0.01, 0.2, abs(.resistanceScores[1]), step=0.01),
sliderInput("l1L", "Low Sensitivity/High resistance", 0.15, 0.5, abs(.resistanceScores[2]), step=0.01),
sliderInput("l1M", "Medium Sensitivity/Med resistance", 0.5, 0.75, abs(.resistanceScores[3]), step=0.01),
sliderInput("l1H", "High Sensitivity/Low resistance", 0.75, 1.0, abs(.resistanceScores[4]), step=0.01),
sliderInput("l1VH", "Very High Sensitivity/No resistance", 0.9, 1.0, abs(.resistanceScores[5]), step=0.01),
sliderInput("ssgr", "Steady state growth rate", -0.1, 0.1,.resistanceScores[6], step=0.01),
sliderInput("l1PressSD", "Pressure Std Dev", 0.1, 1.0, .resistanceScores[7], step=0.01)
sliderInput("l1VL", "Insensitive", 0.01, 0.2, abs(.resistanceScores[1]), step = 0.01),
sliderInput("l1L", "Low Sensitivity/High resistance", 0.15, 0.5, abs(.resistanceScores[2]), step = 0.01),
sliderInput("l1M", "Medium Sensitivity/Med resistance", 0.5, 0.75, abs(.resistanceScores[3]), step = 0.01),
sliderInput("l1H", "High Sensitivity/Low resistance", 0.75, 1.0, abs(.resistanceScores[4]), step = 0.01),
sliderInput("l1VH", "Very High Sensitivity/No resistance", 0.9, 1.0, abs(.resistanceScores[5]), step = 0.01),
sliderInput("ssgr", "Steady state growth rate", -0.1, 0.1,.resistanceScores[6], step = 0.01),
sliderInput("l1PressSD", "Pressure Std Dev", 0.1, 1.0, .resistanceScores[7], step = 0.01)
)
},
title='Layer 1 controls',
footer=tagList(
title = "Layer 1 controls",
footer = tagList(
modalButton("Cancel"),
actionButton("modalOK", "OK")
),
size='s')
size = "s")
)
})
observeEvent(input$modalOK, {
print('Modal ok pressed')
print("Modal ok pressed")
.resistanceScores['nr'] <<- -input$l1VH
.resistanceScores['lr'] <<- -input$l1H
.resistanceScores['mr'] <<- -input$l1M
.resistanceScores['hr'] <<- -input$l1L
.resistanceScores['ins'] <<- -input$l1VL
.resistanceScores['ssgr'] <<- input$ssgr
.resistanceScores['pressSD'] <<- input$l1PressSD
.resistanceScores["nr"] <<- -input$l1VH
.resistanceScores["lr"] <<- -input$l1H
.resistanceScores["mr"] <<- -input$l1M
.resistanceScores["hr"] <<- -input$l1L
.resistanceScores["ins"] <<- -input$l1VL
.resistanceScores["ssgr"] <<- input$ssgr
.resistanceScores["pressSD"] <<- input$l1PressSD
print('Running calc')
print("Running calc")
#.likelihoods$p_ba <<- calcLikelihood(1, .selections$pressStatus)
#.likelihoods$ba_os <<- calcLikelihood(2, .selections$pressStatus)
#.likelihoods$os_es <<- calcLikelihood(3, .selections$pressStatus)
@@ -442,38 +440,52 @@ server <- function(input, output, session) {
output$nodeTable <- DT::renderDataTable(
modelList[[.selections$model]]$nodes,
selection = 'single',options = list(searching = TRUE, pageLength = 10, editable=TRUE),server = TRUE, escape = FALSE,rownames= TRUE
selection = "single",
server = TRUE,
escape = FALSE,
rownames = TRUE,
options = list(searching = TRUE, pageLength = 10, editable = TRUE)
)
output$edgeTable <- DT::renderDataTable(
modelList[[.selections$model]]$edges,
selection = 'single',options = list(searching = TRUE, pageLength = 10, editable=TRUE),server = TRUE, escape = FALSE,rownames= TRUE
selection = "single",
server = TRUE,
escape = FALSE,
rownames = TRUE,
options = list(searching = TRUE, pageLength = 10, editable = TRUE)
)
getLabel <- function(value) {
sign <- ifelse(value<0, "-", "+")
idx <- min(which((abs(value)>=thresholds)==TRUE))
sign <- ifelse(value < 0, "-", "+")
idx <- min(which((abs(value) >= thresholds) == TRUE))
return(paste0(sign, impLabels[idx]))
}
makeBbnGraph <- function(model) {
nodes <- model$nodes
if (.selections$bbnEdges) {labels <- sapply(model$edges$values, getLabel)} else {labels <- rep("", nrow(model$edges))}
if (.selections$bbnEdges) {
labels <- sapply(model$edges$values, getLabel)
} else {
labels <- rep("", nrow(model$edges))
}
edges <- data.frame(
id = rownames(model$edges),
from=match(model$edges$input, nodes$code),
to=match(model$edges$output, nodes$code),
values=model$edges$values,
label=labels,
arrows="to",
stringsAsFactors=FALSE
from = match(model$edges$input, nodes$code),
to = match(model$edges$output, nodes$code),
values = model$edges$values,
label = labels,
arrows = "to",
stringsAsFactors = FALSE
)
if (.selections$bbnNames) {labels <- nodes$name} else {labels <- nodes$code}
if (.selections$bbnNames) {
labels <- nodes$name
} else {
labels <- nodes$code
}
nodeSpacing <- ifelse(.selections$bbnNames, 600, 150)
@@ -486,19 +498,19 @@ server <- function(input, output, session) {
group = nodes$layer,
color = palette[as.integer(nodes$layer)],
code = nodes$code,
stringsAsFactors=FALSE
stringsAsFactors = FALSE
)
edges <- edges[(abs(edges$values)>=.selections$bbnImpact),]
edges <- edges[(abs(edges$values) >= .selections$bbnImpact),]
nodeNet <- nodes[(nodes$code %in% .selections$pressStatus$code[.selections$pressStatus$status %in% c('On')]),]
nodeNet <- nodes[(nodes$code %in% .selections$pressStatus$code[.selections$pressStatus$status %in% c("On")]),]
#save(nodes, edges, nodeNet, file = 'tmp.RData')
#save(nodes, edges, nodeNet, file = "tmp.RData")
if (nrow(nodeNet)>0) {
if (nrow(nodeNet) > 0) {
#do pressures
edgeNet <- edges[edges$from %in% nodeNet$id, ]
idx = 1
idx <- 1
repeat {
nodesToAdd <- nodes[nodes$id %in% edgeNet$to, ]
nodesToAdd <- nodesToAdd[!(nodesToAdd$id %in% nodeNet$id),]
@@ -507,12 +519,14 @@ server <- function(input, output, session) {
edgesToAdd <- edgesToAdd[!(edgesToAdd$id %in% edgeNet$id),]
idx <- idx + 1
if ((idx>20) || ((nrow(nodesToAdd)==0) && (nrow(edgesToAdd)==0))) break
if ((idx > 20) || ((nrow(nodesToAdd) == 0) && (nrow(edgesToAdd) == 0))) break
nodeNet <- rbind(nodeNet, nodesToAdd)
edgeNet <- rbind(edgeNet, edgesToAdd)
} #until finished
} else edgeNet <- edges
} else {
edgeNet <- edges
}
legendDF <- data.frame(
id = 1:length(legends),
@@ -521,10 +535,10 @@ server <- function(input, output, session) {
stringsAsFactors = FALSE
)
visNetwork(nodeNet, edgeNet, width = "100%", main='Bayesian Belief Network', submain=input$modelSelect) %>%
visNetwork(nodeNet, edgeNet, width = "100%", main = "Bayesian Belief Network", submain = input$modelSelect) %>%
visExport() %>%
visLegend(useGroups=FALSE, addNodes=legendDF) %>%
visHierarchicalLayout(nodeSpacing=nodeSpacing, direction='LR') %>%
visLegend(useGroups = FALSE, addNodes = legendDF) %>%
visHierarchicalLayout(nodeSpacing = nodeSpacing, direction = "LR") %>%
visOptions(highlightNearest = TRUE) #%>%
#visInteraction(navigationButtons = TRUE, dragNodes = TRUE, dragView = TRUE, zoomView = TRUE)
}
@@ -535,39 +549,39 @@ server <- function(input, output, session) {
#observe({
# visNetworkProxy("bbnGraphPlot") %>%
# visStabilize(iterations=10)
# visStabilize(iterations = 10)
#})
getModelName <- function() {
paste0('data/', input$modelSelect, '.xlsx')
paste0("data/", input$modelSelect, ".xlsx")
}
genPlot <- function(boxPlot, title) {
if (nrow(boxPlot)>0) {
if (nrow(boxPlot) > 0) {
palette <- brewer.pal(length(legends), "RdYlGn")
#print(palette)
colours <- palette[as.integer(boxPlot$Group)]
#print(paste('Box plot, colours', nrow(boxPlot), length(colours)))
#print(paste("Box plot, colours", nrow(boxPlot), length(colours)))
#cat(colours)
xform <- list(categoryorder = "array",
categoryarray = boxPlot[,1],
zerolinewidth=10)
zerolinewidth = 10)
#
plot_ly(boxPlot, x = boxPlot[,1], y = ~Range, color = colours, colors = palette, type = "box") %>%
layout(xaxis = xform, showlegend=FALSE, title=title)
layout(xaxis = xform, showlegend = FALSE, title = title)
}
}
prepPlot <- function(code="ba", name="Bio-Assemblage") {
prepPlot <- function(code = "ba", name = "Bio-Assemblage") {
if (!is.null(.likelihoods$p_es)) {
inScope <- startsWith(.likelihoods$p_es$code, code)
thisPlot <- .likelihoods$p_es[inScope, c(1,3,4)]
colnames(thisPlot) <- c(name, "Group", "Range")
title <- paste(input$modelSelect, name, 'Box Plot')
title <- paste(input$modelSelect, name, "Box Plot")
genPlot(thisPlot, title)
}
}
@@ -588,33 +602,30 @@ server <- function(input, output, session) {
export <- function(model) {
#Get the network graph
l1 <- orca(prepPlot("ba", "Bio-Assemblage"), 'tmp/layer1.png')
l2 <- orca(prepPlot("op", "Output Processes"),'tmp/layer2.png')
l3 <- orca(prepPlot("es", "Ecosystem Services"), 'tmp/layer3.png')
l1 <- orca(prepPlot("ba", "Bio-Assemblage"), "tmp/layer1.png")
l2 <- orca(prepPlot("op", "Output Processes"),"tmp/layer2.png")
l3 <- orca(prepPlot("es", "Ecosystem Services"), "tmp/layer3.png")
#Save pressure list, confidence levels, node and edge tables in xlsx
l <- list(
pressures = .selections$pressStatus,
nodes = model$nodes,
edges = model$edges,
settings = as.data.frame(cbind(names(.resistanceScores), .resistanceScores), stringsAsFactors=FALSE)
settings = as.data.frame(cbind(names(.resistanceScores), .resistanceScores), stringsAsFactors = FALSE)
)
xl <- write.xlsx(l, 'tmp/dataset.xlsx')
xl <- write.xlsx(l, "tmp/dataset.xlsx")
print('saving xlsx file export tmp/dataset.xlsx')
print("saving xlsx file export tmp/dataset.xlsx")
zipFile <- zipr(paste0('tmp/MESO-', format(Sys.time(), "%m%d_%H%M"), '.zip'), c('tmp/layer1.png', 'tmp/layer2.png', 'tmp/layer3.png', 'tmp/dataset.xlsx'))
zipFile <- zipr(paste0("tmp/MESO-", format(Sys.time(), "%m%d_%H%M"), ".zip"), c("tmp/layer1.png", "tmp/layer2.png", "tmp/layer3.png", "tmp/dataset.xlsx"))
print(paste('zip file complete', zipFile))
print(paste("zip file complete", zipFile))
return(zipFile)
}
output$linkBackgroundData <- downloadHandler(
filename = getModelName(),
content = function(file) {
@@ -623,8 +634,8 @@ server <- function(input, output, session) {
contentType = "application/xlsx"
)
output$download <-downloadHandler(
filename = paste0('MESO-', format(Sys.time(), "%m%d_%H%M"), '.zip'),
output$download <- downloadHandler(
filename = paste0("MESO-", format(Sys.time(), "%m%d_%H%M"), ".zip"),
content = function(file) {
fName <- export(modelList[[.selections$model]])
file.copy(fName, file)