3

I'm writing a new Shiny app, and I would like to plot a spinning 3D scatterplot using plot3d() like this one:

# Spinning 3d Scatterplot
library(rgl)
plot3d(wt, disp, mpg, col="red", size=3)

I'm trying to use something similar to what was done here: shinyRGL examples, with the options renderWebGL({}) and webGLOutput(). But I keep getting this error:

Error in match(x, table, nomatch = 0L) : 'match' requires vector arguments

and I couldn't figure it out why.

This is an example of the dataset I'm using now:

n=100
taxi <- data.frame(conversion=c(rep(1,20),rep(0,80)),
         day = sample(1:7, n, TRUE),
         hour = sample(0:23,n, TRUE),
         source= sample(1:4, n, TRUE),
         service= sample(1:5, n, TRUE),
         relevancy= sample(1:4, n, TRUE),
         tollfree= sample(c(0,1), n, TRUE),
         distance= sample(0:15, n, TRUE),
         similarity= sample(seq(0,1,0.01), n, TRUE),
         simi.names= sample(c('[0,0.25)','[0.25,0.5)','[0.5,0.75)','[0.75,1]'), n, TRUE),
         dist.names= sample(c('[0,1)','[1,2)','[2,3)','[3,4)','[4,15]'), n, TRUE),
         week= sample(1:7, n, TRUE),
         rel= sample(c(1,4), n, TRUE))

and I have this for ui.R:

shinyUI(navbarPage("",
               tabPanel("Data",
                        sidebarLayout(
                          sidebarPanel(
                            selectInput("dataset", h5("Choose a dataset:"), choices = c("taxicabs", "liquor stores")),
                            radioButtons("discrete", h5("I want to discretize:"), choices = c("similarity", "distance","similarity & distance","none"),
                                         inline=F, selected = "none"),
                            radioButtons("agg", h5("I want to aggregate:"), choices = c("day in weekdays/weekends", "relevancy in binary relevancy",
                                                                                        "day in weekdays/weekends &  relevancy in binary relevancy","none"),
                                         inline=F, selected = "none"),
                            checkboxGroupInput("checkGroup", label = h5("Dataset Features:"), 
                                               choices = c("day","hour","source","service","relevancy","tollfree","distance","similarity"), inline = F,
                                               selected = c("day","hour","source","service","relevancy","tollfree","distance","similarity"))
                          ),
                          mainPanel(
                            numericInput("obs", label = h5("Number of observations to view"), 15, min = 10, max = 20, step = 1),
                            tableOutput("view"),
                            tableOutput("var")
                          )
                        )
               ),
               tabPanel("Model",
                        h3("Best logistic model with logit link and variable selection via stepwise AIC "),
                        verbatimTextOutput("model"),
                        downloadButton('downloadReport',label = 'Download coefficients'),
                        h3("MSE"),
                        tableOutput("measures"),
                        h3("Response fit"),
                        plotOutput('plot')
               ),
               tabPanel("Visualize Fit on Features",
                        fluidRow(                           
                          column(4, selectInput("featureDisplay_x", 
                                                label = h3("X-Axis Feature"), 
                                                choices = NULL)),
                          column(4, selectInput("featureDisplay_y", 
                                                label = h3("Y-Axis Feature"), 
                                                choices = NULL)) 
                        ),
                        fluidRow(
                          column(4,
                                 plotOutput("distPlotA")
                          ),                              
                          column(4,
                                 plotOutput("distPlotB")      
                          ),
                          column(4,
                                 webGLOutput("webGL")
                          )
                        )
               )

))

and this for server.R

options(rgl.useNULL=TRUE)
library(shiny)
library(reshape2)
library(ggplot2)
library(dplyr)
library(rgl)
library(shinyRGL)
source("webGLParser.R")

shinyServer(function(input, output, session) {
datasetInput <- reactive({
switch(input$dataset,
       "taxicabs" = taxi,
       "liquor stores" = liq)
})

observe({
choices <- c("day", "hour", "source", "service", "relevancy", "tollfree", "distance", "similarity")
if (grepl("day in weekdays/weekends", input$agg))  {
  choices[1] <- "week"
}
if (grepl("relevancy", input$agg))  {
  choices[5] <- "rel"
}      
if (grepl("similarity", input$discrete)) {
  choices[8] <- "simi.names"
}
if (grepl("distance", input$discrete)) {
  choices[7] <- "dist.names"
}
updateCheckboxGroupInput(session, "checkGroup", choices = choices,
                         inline = F, selected = choices)
})


datasetagg <- reactive({ 
cg <- input$checkGroup
dis <- input$discrete
cg_not_d_or_s <- cg[!(cg %in% c("distance", "similarity"))]
if(input$discrete == "similarity & distance") {
  #all discrete 
  right_join(
    datasetInput() %>%
      select_(.dots = cg) %>%
      group_by_(.dots = cg) %>%
      summarise(count=n()),
    datasetInput() %>%
      filter(conversion==1) %>%
      select_(.dots = cg) %>%
      count_(vars = cg)
  ) %>% mutate(prop.conv = n/count)
} else if(input$discrete == "distance") {
  cg_not_dis <- cg[cg != "similarity"]
  # one continuous
  right_join(
    datasetInput() %>%
      group_by_(.dots = cg_not_dis) %>%
      summarise_(.dots = setNames(c("mean(similarity)", "n()"),
                                  c("simi.mean", "count"))) %>%
      select_(.dots = c(cg_not_dis, "simi.mean", "count")),
    datasetInput() %>%
      filter(conversion==1) %>%
      select_(.dots = cg_not_dis) %>%
      count_(vars = cg_not_dis)
  ) %>% mutate(prop.conv = n/count)
} else if(input$discrete == "similarity") {
  cg_not_dis <- cg[cg != "distance"]
  # one continuous
  right_join(
    datasetInput() %>%
      group_by_(.dots = cg_not_dis) %>%
      summarise_(.dots = setNames(c("mean(distance)", "n()"),
                                  c("dist.mean", "count"))) %>%
      select_(.dots = c(cg_not_dis, "dist.mean", "count")),
    datasetInput() %>%
      filter(conversion==1) %>%
      select_(.dots = cg_not_dis) %>%
      count_(vars = cg_not_dis)
  ) %>% mutate(prop.conv = n/count)
} else if(input$discrete == "none") {
  # two  
  right_join(
    datasetInput() %>%
      select_(.dots = cg) %>%
      group_by_(.dots = cg_not_d_or_s) %>%
      summarise(dist.mean=mean(distance), simi.mean=mean(similarity), count=n()),
    datasetInput() %>%
      filter(conversion==1) %>%
      select_(.dots = cg) %>%
      count_(vars = cg_not_d_or_s)
  ) %>% mutate(prop.conv = n/count)
}
})

# head of the table  
output$view <- renderTable({
head(datasetagg(), n = input$obs)
})

output$var <- renderPrint({
if(sum(sapply(droplevels(datasetagg()),function(x)length(levels(x)))==1)==0) {
  paste(' *** ' ) 
} else if (sum(sapply(droplevels(datasetagg()),function(x)length(levels(x)))==1)>=1){
  paste('***Warning: ' ,names(which(sapply(droplevels(datasetagg()),function(x)length(levels(x)))==1)), 'have just 1 level and should not be selected fo the model.' )
}  
})

name <- reactive({ 
names.datasetagg <- names(datasetagg())
names.datasetagg[names.datasetagg == 'hour'] <- paste('I((0.2034*sin(-0.298*as.numeric(',names.datasetagg[names.datasetagg == 'hour'],')+21.679)+0.3177))')
names.datasetagg <- as.formula(paste0('cbind(n,count) ~ ',paste(names.datasetagg[! (names.datasetagg %in% c("n","count","prop.conv"))],collapse = '+')))
}) 

fit <- reactive({ 
step(glm(name(), family=binomial(logit), weights = count, data=datasetagg()),
   scope=~., trace=0, direction='both', k=2)
}) 

# model
output$model <- renderPrint({
summary(fit()) #best model glm.step.aic.l
})

# measures
output$measures <- renderPrint({ 
sqrt((sum((fit()$fitted.values-datasetagg()[,'prop.conv'])^2 * datasetagg()[,'count']))/sum(datasetagg()[,'count']))
})

  # download report
output$downloadReport <- downloadHandler(
filename = "mycoefficients.json",

content = function(file) {
  write.table(coefficients(fit()), file, sep="\t")
})

 # plot fit
output$plot <- renderPlot({
ggplot(data.frame(datasetagg(),pred=fit()$fitted.values), aes(x=prop.conv)) + 
  geom_histogram(aes(y=..density..),     
                 binwidth=.02,
                 colour="black", fill="white") +
  geom_density(aes(x=pred),alpha=.2, fill="#E4002B")+xlab("Proportion of convertions")
})

# graphs
observe({
updateSelectInput(session, "featureDisplay_x", 
                  choices =ifelse(input$checkGroup=='distance',"dist.mean",ifelse(input$checkGroup=='similarity',"simi.mean",input$checkGroup)),
                  selected=input$checkGroup[1])
updateSelectInput(session, "featureDisplay_y", 
                  choices =ifelse(input$checkGroup=='distance',"dist.mean",ifelse(input$checkGroup=='similarity',"simi.mean",input$checkGroup)),
                  selected=input$checkGroup[6])
})

# dataset for prediction
a <- data.frame(matrix(c(1,18,1,1,1,0,5,0.25,'[0,0.25)','[0,1)',1,1),nrow=1))
names(a) <- c('day','hour','source','service','relevancy','tollfree','dist.mean','simi.mean','simi.names','dist.names','week','rel')
a[,c('dist.mean','simi.mean',"hour")] <- lapply(a[,c('dist.mean','simi.mean',"hour")],function(x) as.numeric(as.character(x)))


xvarData <- reactive({ 
col <- input$featureDisplay_x
b <- a[names(a) %in% names(datasetagg())[!(names(datasetagg()) %in% c('count', 'n', 'prop.conv'))]]
b <- b[-which(names(b) %in% col)]

sel <- c(names(datasetagg())[!(names(datasetagg()) %in% c('count', 'n', 'prop.conv'))],'mean')
pred <- predict(fit(),newdata = data.frame(datasetagg() %>%  group_by_(.dots = col) %>% summarise(mean = mean(prop.conv)) %>% 
                                           cbind(b) %>% 
                                             select(one_of(sel)))
                ,type="response")

datasetagg() %>%  group_by_(.dots = col) %>% summarise(mean = mean(prop.conv)) %>% 
  cbind(b) %>% 
  select(one_of(sel)) %>%  
  mutate(pred=pred) %>% 
  select_(.dots = c(col,'mean','pred'))
})

p1 <- function(data){
ggplot(melt(data(),id.vars = input$featureDisplay_x),aes_string(x=input$featureDisplay_x,y='value',colour='variable'))+
  scale_colour_manual(values=c("#7A99AC","#E4002B"),labels=c("Average", "Predict"),name  =" ")+
  geom_point() + ylab("proportion of conversions") + ylim(0, 1)
}
  output$distPlotA <- renderPlot(function() {
 plot=p1(xvarData)
 print(plot)
})


yvarData <- reactive({ 
col <- input$featureDisplay_y
b <- a[names(a) %in% names(datasetagg())[!(names(datasetagg()) %in% c('count', 'n', 'prop.conv'))]]
b <- b[-which(names(b) %in% col)]

sel <- c(names(datasetagg())[!(names(datasetagg()) %in% c('count', 'n', 'prop.conv'))],'mean')
pred <- predict(fit(),newdata = data.frame(datasetagg() %>%  group_by_(.dots = col) %>% summarise(mean = mean(prop.conv)) %>% 
                                             cbind(b) %>% 
                                             select(one_of(sel)))
                ,type="response")

  datasetagg() %>%  group_by_(.dots = col) %>% summarise(mean = mean(prop.conv)) %>% 
  cbind(b) %>% 
  select(one_of(sel)) %>%  
  mutate(pred=pred) %>% 
  select_(.dots = c(col,'mean','pred'))
})

p2 <- function(data){
ggplot(melt(data(),id.vars = input$featureDisplay_y),aes_string(x=input$featureDisplay_y,y='value',colour='variable'))+
  scale_colour_manual(values=c("#7A99AC","#E4002B"),labels=c("Average", "Predict"),name  =" ")+
  geom_point() + ylab("proportion of conversions") + ylim(0, 1)
 }
  output$distPlotB <- renderPlot(function() {
plot=p2(yvarData)
print(plot)

})

xyvarData <- reactive({ 
colx <- input$featureDisplay_x
coly <- input$featureDisplay_y
b <- a[names(a) %in% names(datasetagg())[!(names(datasetagg()) %in% c('count', 'n', 'prop.conv'))]]
b <- b[-which(names(b) %in% c(colx,coly))]

sel <- c(names(datasetagg())[!(names(datasetagg()) %in% c('count', 'n', 'prop.conv'))],'mean')
pred <- predict(fit(),newdata = data.frame(datasetagg() %>%  group_by_(.dots = colx,coly) %>% summarise(mean = mean(prop.conv)) %>% 
                                             cbind(b) %>% 
                                             select(one_of(sel)))
                ,type="response")

  datasetagg() %>%  group_by_(.dots = colx, coly) %>% summarise(mean = mean(prop.conv)) %>% 
  cbind(b) %>% 
  select(one_of(sel)) %>%  
  mutate(pred=pred) %>% 
  select_(.dots = c(colx,coly,'mean','pred'))
})

output$webGL <- renderWebGL(function() { # the error is here!!!
  output$webGL <- renderWebGL(function() {
rgl::plot3d(xyvarData()[,1],xyvarData()[,2],xyvarData()[,'mean'],col="#7A99AC",zlab = "proportion of conversions")
rgl::plot3d(xyvarData()[,1],xyvarData()[,2],xyvarData()[,'pred'],col="#E4002B",add=T)
})
})


})

I'm sorry for the long code, I just want it to make sure it was reproducible.

Any suggestions? Thanks for the help!

EDIT: I also tried with plotly without success. I got the templates from here: plotly templates for Shiny and I'm using this at UI.R:

graphOutput("ScatterPlot")

and this at Server.R:

  output$ScatterPlot <- renderGraph(function() {
## Create your Plotly graph
trace1 <- list(
  x = xyvarData()[,1],
  y = xyvarData()[,2],
  z = xyvarData()[,'mean'],
  mode = "markers", 
  name = "trace0_y", 
  marker = list(
    size = 12, 
    line = list(
      color = "rgba(217, 217, 217, 0.14)", 
      width = 0.5
    ), 
    opacity = 0.8
  ), 
  type = "scatter3d"
)
trace2 <- list(
  x = xyvarData()[,1],
  y = xyvarData()[,2],
  z = xyvarData()[,'pred'],
  mode = "markers", 
  name = "trace1_y", 
  marker = list(
    color = "rgb(127, 127, 127)", 
    size = 12, 
    symbol = "circle", 
    line = list(
      color = "rgb(204, 204, 204)", 
      width = 1
    ), 
    opacity = 0.9
  ), 
  type = "scatter3d"
)
data <- list(trace1, trace2)
layout <- list(
  autosize = FALSE, 
  width = 500, 
  height = 500, 
  margin = list(
    l = 0, 
    r = 0, 
    b = 0, 
    t = 65
  )
)

# define data
data <- list(trace1, trace2)
# define layout information
layout <- list(
  autosize = FALSE, 
  width = 500, 
  height = 500, 
  margin = list(
    l = 0, 
    r = 0, 
    b = 0, 
    t = 65
  )
)

# This sends message up to the browser client, which will get fed through to
# Plotly's javascript graphing library embedded inside the graph
return(list(
  list(
    id="trendPlot",
    task="newPlot",
    data=data,
    layout=layout
  )
))
})   

Instead of webGLOutput() and renderWebGL({}).

1

1 Answer 1

6

Ok, I just got it. Thanks to Joe Cheng, I decided to use threejs and work neatly!

Now, I have at UI.R

uiOutput("ScatterPlot")

And at Server.R

  output$plott <- renderScatterplotThree({

  col <- c(rep("#7A99AC",table(xyvarData()[,'variable'])[[1]]),rep("#E4002B",table(xyvarData()[,'variable'])[[2]]))
  scatterplot3js(xyvarData()[,1],xyvarData()[,2],xyvarData()[,'value'], color=col, size=0.5, 
             axisLabels=c(input$featureDisplay_x,"prop.conversions",input$featureDisplay_y),zlim=c(0,1))  

})
output$ScatterPlot <- renderUI({
  scatterplotThreeOutput("plott")
})

Instead of webGLOutput() and renderWebGL({}).

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.