\name{intersectDiagram}
\alias{intersectDiagram}
\title{Display set intersections}
\description{Display set intersections as rows of rectangles.}
\usage{
 intersectDiagram(x,pct=FALSE,show.nulls=FALSE,xnames=NULL,sep="+",
  mar=c(0,0,3,0),main="Intersection Diagram",cex=1,col=NULL,
  minspacing=NA,all.intersections=FALSE,include=NULL,null.label="Non-set")
}
\arguments{
 \item{x}{A list containing as many numeric vectors as there are sets. The
  first vector contains the counts or percentages of the elements that are
  only in one set, the next vector contains the counts or percentages of 
  elements that are in two sets and so on. A matrix of set membership
  indicators or a two column matrix of object identifiers and attribute
  identifiers can be passed - see Details.}
 \item{pct}{Whether to display counts (FALSE) or percentages (TRUE) of the
  number of entities.}
 \item{show.nulls}{Whether to display the number of original objects that 
  are not members of any set. Any value that is not NA will become the 
  label for this category.}
 \item{xnames}{Optional user supplied names for the set categories (see
  Details).}
 \item{sep}{The separator to use between category names (see Details).}
 \item{mar}{The margins for the diagram. The margins that were in effect when
  the function is called are restored.}
 \item{main}{The title for the diagram.}
 \item{col}{Colors for the sets (see Details).}
 \item{cex}{Character expansion for the intersection labels.}
 \item{minspacing}{The minimum spacing between the rectangles (see Details).}
 \item{all.intersections}{Whether to display all intersections, even if empty
  (Dangerous - see Detail).}
 \item{include}{Which set identifiers to include in the diagram (see Details).}
 \item{null.label}{The label for the non-set entities if displayed.}
}
\details{
 \samp{intersectDiagram} displays rows of optionally colored rectangles that
 represent the intersections of set memberships (attributes) of a set of objects.
 The topmost row represents the intersections of the fewest sets, and
 succeeding rows represent the intersections of more sets. If there were objects
 in the original data set that were not members of any set, any percentages
 calculated will reflect this. By setting \samp{show.nulls} to TRUE, the counts
 or percentages of such objects will be displayed below the intersections over
 an empty rectangle scaled to the count or percentage.

 Important - If the \samp{all.intersections} argument is TRUE, all intersections
 will be displayed, whether empty or not (see the example). This is mostly for
 demonstration purposes, and if the number of sets is large, is likely to produce
 a very messy diagram. Similarly, sets with large numbers of
 intersections that are populated will require very large displays to be readable,
 even if there are small numbers in the intersections. If you would like to see
 this in action, pass the data frame \samp{setdf} in the \link{categoryReshape}
 example to \samp{intersectDiagram} with \samp{all.intersections} TRUE.

 \samp{intersectDiagram} does not attempt to display the set intersections as
 a pattern of overlapping geometric figures, but rather the relative numbers of
 objects sharing each intersection. More than three intersecting sets generally
 produce a complex and difficult to interpret Venn diagram, and this provides an
 alternative way to display the size of intersections between larger numbers
 of sets.

 \samp{intersectDiagram} now allows the user to display only part of the 
 set intersections, which is useful for analyzing very complex intersections.
 This is controlled by the \samp{include} argument. This defaults to all sets or 
 attributes when \samp{include=NULL}. If one or more of the labels of the sets or 
 attributes is passed, only the intersections containing those labels will be 
 displayed. See examples 2 and 3 below.
 
 Each set (attribute) is assigned a color if \samp{col} is not NA. \samp{rainbow}
 is called if \samp{col} is NULL, otherwise the colors passed are used. For each
 intersection, the colors representing the sets intersecting are included in
 the rectangle.
 
 The strings displayed on each rectangle are taken from the argument
 \samp{xnames} unless that is NULL, then the \samp{names} of the intersectList
 object passed as \samp{x} or returned from the call to \samp{makeIntersectList}.
 
 If a matrix or data frame of set membership indicators is passed as \samp{x},
 it will be passed to \link{makeIntersectList} for conversion. Each column must
 represent a set, and the values in the columns must be 0 or 1, or FALSE or TRUE.
 Similarly, if a matrix or data frame in which the first column is object
 identifiers and the second column is attributes, this will be passed to
 \samp{makeIntersectList}.

 The spacing between the largest rectangles is controlled by \samp{minspacing}.
 \samp{minspacing} is in units of object counts and defaults to 0.1 times the
 largest number of objects in an intersection. When the number of objects in
 different intersections at a given level varies widely, the labels of
 intersections with few objects may overlap if they are wide relative to the
 rectangle representing the number of objects. This can be corrected by
 passing a \samp{minspacing} argument that will increase the space between
 rectangles and/or decreasing the character size of the labels. If the labels
 for each set are relatively long, setting \samp{namesep="\n"} may help. Note 
 that if a different separator is passed, that separator must be explicitly
 passed in any subsequent calls using the same \samp{intersectList} object - see
 examples 1 to 3 below.
}
\value{
 Returns the intersectionList object invisibly.
}
\keyword{misc}
\author{Jim Lemon}
\seealso{\link{makeIntersectList}, \link{getIntersectList}, \link{categoryReshape}}
\examples{
 # create a matrix where each row represents an element and
 # a 1 (or TRUE) in each column indicates that the element is a member
 # of that set.
 druguse<-matrix(c(sample(c(0,1),200,TRUE,prob=c(0.15,0.85)),
  sample(c(0,1),200,TRUE,prob=c(0.35,0.65)),
  sample(c(0,1),200,TRUE,prob=c(0.5,0.5)),
  sample(c(0,1),200,TRUE,prob=c(0.9,0.1))),ncol=4)
 colnames(druguse)<-c("Alc","Tob","THC","Amp")
 druglist<-makeIntersectList(druguse,sep="\n")
 # first display it as counts
 intersectDiagram(druglist,main="Patterns of drug use",sep="\n")
 # then display only the intersections containing "Alc"
 intersectDiagram(druglist,main="Patterns of drug use (Alcohol users only)",
  sep="\n",include="alc")
 # now display only the intersections containing "Amp"
 intersectDiagram(druglist,main="Patterns of drug use (Speed users only)",
  sep="\n",include="amp")
 # then as percent with non.members, passing the initial matrix
 intersectDiagram(druguse,pct=TRUE,show.nulls=TRUE)
 # alter the data to have more multiple intersections
 druguse[which(as.logical(druguse[,1]))[1:40],2]<-1
 druguse[which(as.logical(druguse[,1]))[31:70],3]<-1
 druguse[,4]<-sample(c(0,1),200,TRUE,prob=c(0.9,0.1))
 intersectDiagram(druguse,main="Smaller font in labels",
  col=c("gray20","gray40","gray60","gray80"),cex=0.8)
 # transform the spacing - usually makes it too close, first try minspacing
 intersectDiagram(druguse,col="gray",main="Minimum spacing = 30 cases",
  minspacing=30)
 # then try cex - may need both for large differences
 intersectDiagram(druguse,main="Very boring single color",col="gray",cex=0.8)
 # create a matrix with empty intersections
 druguse<-matrix(c(sample(c(0,1),20,TRUE),
  sample(c(0,1),20,TRUE),
  sample(c(0,1),20,TRUE),
  sample(c(0,1),20,TRUE)),ncol=4)
 # show only the populated intersections
 intersectDiagram(druguse,main="Display only populated intersections")
 # show all intersections
 intersectDiagram(druguse,main="Display empty intersections",all.intersections=TRUE)
}