11

I know that I can create an expression tree in R using the substitute function. Let's say that I generate the following expression tree:

expT <- substitute(a+(2*b+c))

Is it possible to visualize the expression tree in R, producing something like:

Expression Tree

I know that ( is also a function in R, but I would like to omit that in the plot.

11
+500

Here is an approach taking advantage of the function utils::getParseData and borrowing from a function written for the parser package and using igraph for the visuals. The linked function almost does what you wanted, but the data returned by the getParseData function has blank nodes with the numerical values/symbols/operators etc. on the leaves. This makes sense if you try to parse functions or ternary expressions or more complicated things.

This function simply creates an edgelist from the parse data.

## https://github.com/halpo/parser/blob/master/R/plot.parser.R
## Modified slightly to return graph instead of print/add attr
parser2graph <- function(y, ...){
    y$new.id <- seq_along(y$id)
    h <- graph.tree(0) + vertices(id = y$id, label= y$text)
    for(i in 1:nrow(y)){
        if(y[i, 'parent'])
            h <- h + edge(c(y[y$id == y[i, 'parent'], 'new.id'], y[i, 'new.id']))
    }
    h <- set_edge_attr(h, 'color', value='black')
    return(h)
}

The next function collapses the parse tree by removing all the '(){}' and remaining gaps. The idea is to first move all the labels up one level in the tree, then clip the leaves. And finally all the gaps from nested expressions ('(){}') are removed by creating/destroying edges. I colored the edges blue where levels of nesting from brackets/braces were removed.

## Function to collapse the parse tree (removing () and {})
parseTree <- function(string, ignore=c('(',')','{','}'), ...) {
    dat <- utils::getParseData(parse(text=string))
    g <- parser2graph(dat[!(dat$text %in% ignore), ])
    leaves <- V(g)[!degree(g, mode='out')]                             # tree leaves
    preds <- sapply(leaves, neighbors, g=g, mode="in")                 # their predecessors
    vertex_attr(g, 'label', preds) <- vertex_attr(g, 'label', leaves)  # bump labels up a level
    g <- g - leaves                                                    # remove the leaves
    gaps <- V(g)[!nchar(vertex_attr(g, 'label'))]                      # gaps where ()/{} were
    nebs <- c(sapply(gaps, neighbors, graph=g, mode='all'))            # neighbors of gaps
    g <- add_edges(g, nebs, color='blue')                              # edges around the gaps
    g <- g - V(g)[!nchar(vertex_attr(g, 'label'))]                     # remove leaves/gaps
    plot(g, layout=layout.reingold.tilford, ...)
    title(string, cex.main=2.5)
}

An example, slightly more nested expression. The animation shows how original tree is collapsed.

## Example string
library(igraph)
string <- "(a/{5})+(2*b+c)"

parseTree(string,  # plus some graphing stuff
          vertex.color="#FCFDBFFF", vertex.frame.color=NA,
          vertex.label.font=2, vertex.label.cex=2.5,
          vertex.label.color="darkred", vertex.size=25,
          asp=.7, edge.width=3, margin=-.05)

enter image description here

3
  • 1
    Amazing answer thank you! I think this is the best answer so far so I will accept it. – Gumeo Nov 3 '15 at 12:44
  • 2
    Note, that if the input is not a string, but an expression from substitute, you can use deparse to get the corresponding string. – Gumeo Nov 3 '15 at 13:04
  • 1
    @bunk Awesome answer. This question seems related? Any help: stackoverflow.com/q/33473107/1000343 – Tyler Rinker Nov 4 '15 at 2:50
5

The following gets most of the way there. It mimics pryr:::tree to recursively examine the call tree, then assigns data.tree Nodes. I would have preferred igraph but it is intolerant of duplicate node names (e.g. + appearing twice). I also cannot get dendrogram to label any of the branches other than the root.

#install.packages("data.tree")
library(data.tree)

make_tree <- function(x) {
  if (is.atomic(x) && length(x) == 1) {
    as.character(deparse(x)[1])
  } else if (is.name(x)) {
    x <- as.character(x)
    if (x %in% c("(", ")")) {
      NULL
    } else {
      x
    }
  } else if (is.call(x)) {
    call_items <- as.list(x)
    node <- call_items[[1]]
    call_items <- call_items[-1]
    while (as.character(node) == "(" && length(call_items) > 0) {
      node <- call_items[[1]]
      call_items <- call_items[-1]
    }
    if (length(call_items) == 0) 
      return(make_tree(node))
    call_node <- Node$new(as.character(node))
    for (i in 1:length(call_items)) {
      res <- make_tree(call_items[[i]])
      if (is.environment(res))
        call_node$AddChildNode(res)
      else
        call_node$AddChild(res)
    }
    call_node
  } else
    typeof(x)
}

tree <- make_tree(quote(a+(2*b+c)))
print(tree)
plot(as.dendrogram(tree, edgetext = T), center = T, type = "triangle", yaxt = "n")

Which gives a reasonable text output:

      levelName
1 +            
2  ¦--a        
3  °--+        
4      ¦--*    
5      ¦   ¦--2
6      ¦   °--b
7      °--c    

and a graphic. The multiplication symbol doesn't appear in the mid-tree node (I can't figure out why) but otherwise, I think this does the job. call tree plot

3

Here's some code and results that may be helpful and least to the point of being able to "walk" the "parse tree":

> parse( text="a+(2*b+c)")
expression(a+(2*b+c))
> parse( text="a+(2*b+c)")[[1]]
a + (2 * b + c)
> parse( text="a+(2*b+c)")[[1]][[1]]
`+`
> parse( text="a+(2*b+c)")[[1]][[2]]
a
> parse( text="a+(2*b+c)")[[1]][[3]]
(2 * b + c)
> parse( text="a+(2*b+c)")[[1]][[4]]
Error in parse(text = "a+(2*b+c)")[[1]][[4]] : subscript out of bounds
> parse( text="a+(2*b+c)")[[1]][[3]][[1]]
`(`
> parse( text="a+(2*b+c)")[[1]][[3]][[2]]
2 * b + c
> parse( text="a+(2*b+c)")[[1]][[3]][[2]][[1]]
`+`
> parse( text="a+(2*b+c)")[[1]][[3]][[2]][[2]]
2 * b
> parse( text="a+(2*b+c)")[[1]][[3]][[2]][[3]]
c
> parse( text="a+(2*b+c)")[[1]][[3]][[2]][[2]][[1]]
`*`
> parse( text="a+(2*b+c)")[[1]][[3]][[2]][[2]][[2]]
[1] 2
> parse( text="a+(2*b+c)")[[1]][[3]][[2]][[2]][[3]]
b

I thought that I had seen a posting in R-help or r-devel by Thomas Lumley or Luke Tierney that did this, but have so far failed to locate it. I did find a posting by @G.Grothendieck that programmatically pulls apart a parse tree that you might build upon:

 e <- parse(text = "a+(2*b+c)") 
my.print <- function(e) { 
  L <- as.list(e) 
  if (length(L) == 0) return(invisible()) 
  if (length(L) == 1) 
     print(L[[1]]) 
     else sapply(L, my.print) 
return(invisible()) } 
my.print(e[[1]])
#----- output-----
`+`
a
`(`
`+`
`*`
[1] 2
b
c
2
  • +1 I am aware of how I would walk the parse tree, but this might be useful for someone that stumbles onto this question. – Gumeo Oct 29 '15 at 17:23
  • 1
    Right. I was not expecting a check, since it is only illustrating that parse trees are basically lists. – IRTFM Oct 29 '15 at 17:38
2

It’s definitely possible but I am not aware of an existing function to do so. That said, it’s a nice exercise. Have a look at Walking the AST with recursive functions (and do read the whole chapter) for basic instructions on how to operate on an expression tree.

From that, the rest is “relatively” straightforward:

  • For each node, determine the symbol to be printed.
  • Maintain a (relative) coordinate for the current node. When recursing the expression, this coordinate gets updated depending on what you do; for instance, you know that the arguments of a function call need to be centred below its call, so you can update the y coordinate accordingly, and then calculate x depending on how many arguments there are. Operators are just a special case of that.

Finally, you can use the symbols alongside their coordinates thus calculated to plot them, relative to each other.

5
  • (As usual I’d appreciate an explanation for downvotes.) – Konrad Rudolph Oct 29 '15 at 17:17
  • 2
    +1 I am going through adv-R right now :). I was hoping to find a ready implementation. I will try to implement it myself. In case someone has an answer with an actual implementation I will accept your answer in the following week. I did not downvote your answer btw. – Gumeo Oct 29 '15 at 17:19
  • 2
    @Gumeo Good luck. It’s definitely not hard once the concept of a parse tree is understood, but it’s a fair bit of work. – Konrad Rudolph Oct 29 '15 at 17:27
  • @Gumeo if you implement this wrap it up as a generalizable package. This would work for parse trees in language as well. – Tyler Rinker Oct 30 '15 at 11:53
  • @TylerRinker it is on my agenda. – Gumeo Oct 30 '15 at 11:54

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.