#' @name clustering
#' @rdname clustering
-#' @aliases clusteringTask1 computeClusters1 computeClusters2
+#' @aliases clusteringTask1 clusteringTask2 computeClusters1 computeClusters2
#'
#' @title Two-stage clustering, withing one task (see \code{claws()})
#'
#' and then WER distances computations, before applying the clustering algorithm.
#' \code{computeClusters1()} and \code{computeClusters2()} correspond to the atomic
#' clustering procedures respectively for stage 1 and 2. The former applies the
-#' clustering algorithm (PAM) on a contributions matrix, while the latter clusters
-#' a chunk of series inside one task (~max nb_series_per_chunk)
+#' first clustering algorithm on a contributions matrix, while the latter clusters
+#' a set of series inside one task (~nb_items_clust1)
#'
#' @param indices Range of series indices to cluster in parallel (initial data)
#' @param getContribs Function to retrieve contributions from initial series indices:
#' \code{getContribs(indices)} outpus a contributions matrix
-#' @param contribs matrix of contributions (e.g. output of \code{curvesToContribs()})
-#' @param distances matrix of K1 x K1 (WER) distances between synchrones
#' @inheritParams computeSynchrones
#' @inheritParams claws
#'
-#' @return For \code{clusteringTask1()} and \code{computeClusters1()}, the indices of the
-#' computed (K1) medoids. Indices are irrelevant for stage 2 clustering, thus
-#' \code{computeClusters2()} outputs a big.matrix of medoids
-#' (of size limited by nb_series_per_chunk)
+#' @return For \code{clusteringTask1()}, the indices of the computed (K1) medoids.
+#' Indices are irrelevant for stage 2 clustering, thus \code{clusteringTask2()}
+#' outputs a big.matrix of medoids (of size LxK2, K2 = final number of clusters)
NULL
#' @rdname clustering
#' @export
-clusteringTask1 = function(
- indices, getContribs, K1, nb_series_per_chunk, ncores_clust=1, verbose=FALSE, parll=TRUE)
+clusteringTask1 = function(indices, getContribs, K1, algoClust1, nb_items_clust1,
+ ncores_clust=1, verbose=FALSE, parll=TRUE)
{
- if (verbose)
- cat(paste("*** Clustering task 1 on ",length(indices)," lines\n", sep=""))
-
if (parll)
{
- cl = parallel::makeCluster(ncores_clust)
+ cl = parallel::makeCluster(ncores_clust, outfile = "")
parallel::clusterExport(cl, varlist=c("getContribs","K1","verbose"), envir=environment())
}
while (length(indices) > K1)
{
- indices_workers = .spreadIndices(indices, nb_series_per_chunk)
+ indices_workers = .spreadIndices(indices, nb_items_clust1)
+ if (verbose)
+ cat(paste("*** [iterated] Clustering task 1 on ",length(indices)," series\n", sep=""))
indices <-
if (parll)
{
unlist( parallel::parLapply(cl, indices_workers, function(inds) {
require("epclust", quietly=TRUE)
- inds[ computeClusters1(getContribs(inds), K1, verbose) ]
+ inds[ algoClust1(getContribs(inds), K1) ]
}) )
}
else
{
unlist( lapply(indices_workers, function(inds)
- inds[ computeClusters1(getContribs(inds), K1, verbose) ]
+ inds[ algoClust1(getContribs(inds), K1) ]
) )
}
}
#' @rdname clustering
#' @export
-clusteringTask2 = function(medoids, K2,
- getRefSeries, nb_ref_curves, nb_series_per_chunk, ncores_clust=1,verbose=FALSE,parll=TRUE)
+clusteringTask2 = function(medoids, K2, algoClust2, getRefSeries, nb_ref_curves,
+ nb_series_per_chunk, sync_mean, nbytes,endian,ncores_clust=1,verbose=FALSE,parll=TRUE)
{
if (verbose)
- cat(paste("*** Clustering task 2 on ",nrow(medoids)," lines\n", sep=""))
+ cat(paste("*** Clustering task 2 on ",ncol(medoids)," synchrones\n", sep=""))
- if (nrow(medoids) <= K2)
+ if (ncol(medoids) <= K2)
return (medoids)
- synchrones = computeSynchrones(medoids,
- getRefSeries, nb_ref_curves, nb_series_per_chunk, ncores_clust, verbose, parll)
- distances = computeWerDists(synchrones, ncores_clust, verbose, parll)
- medoids[ computeClusters2(distances,K2,verbose), ]
-}
-
-#' @rdname clustering
-#' @export
-computeClusters1 = function(contribs, K1, verbose=FALSE)
-{
- if (verbose)
- cat(paste(" computeClusters1() on ",nrow(contribs)," lines\n", sep=""))
- cluster::pam(contribs, K1, diss=FALSE)$id.med
-}
-
-#' @rdname clustering
-#' @export
-computeClusters2 = function(distances, K2, verbose=FALSE)
-{
+ synchrones = computeSynchrones(medoids, getRefSeries, nb_ref_curves,
+ nb_series_per_chunk, sync_mean, ncores_clust, verbose, parll)
+ distances = computeWerDists(synchrones, nbytes, endian, ncores_clust, verbose, parll)
if (verbose)
- cat(paste(" computeClusters2() on ",nrow(distances)," lines\n", sep=""))
- cluster::pam(distances, K2, diss=TRUE)$id.med
+ cat(paste(" algoClust2() on ",nrow(distances)," items\n", sep=""))
+ medoids[ ,algoClust2(distances,K2) ]
}
#' computeSynchrones
#' @param nb_ref_curves How many reference series? (This number is known at this stage)
#' @inheritParams claws
#'
-#' @return A big.matrix of size K1 x L where L = data_length
+#' @return A big.matrix of size L x K1 where L = length of a serie
#'
#' @export
-computeSynchrones = function(medoids, getRefSeries,
- nb_ref_curves, nb_series_per_chunk, ncores_clust=1,verbose=FALSE,parll=TRUE)
+computeSynchrones = function(medoids, getRefSeries, nb_ref_curves,
+ nb_series_per_chunk, sync_mean, ncores_clust=1,verbose=FALSE,parll=TRUE)
{
- if (verbose)
- cat(paste("--- Compute synchrones\n", sep=""))
-
computeSynchronesChunk = function(indices)
{
if (parll)
requireNamespace("synchronicity", quietly=TRUE)
require("epclust", quietly=TRUE)
synchrones <- bigmemory::attach.big.matrix(synchrones_desc)
- counts <- bigmemory::attach.big.matrix(counts_desc)
+ if (sync_mean)
+ counts <- bigmemory::attach.big.matrix(counts_desc)
medoids <- bigmemory::attach.big.matrix(medoids_desc)
m <- synchronicity::attach.mutex(m_desc)
}
ref_series = getRefSeries(indices)
- nb_series = nrow(ref_series)
+ nb_series = ncol(ref_series)
- #get medoids indices for this chunk of series
+ # Get medoids indices for this chunk of series
mi = computeMedoidsIndices(medoids@address, ref_series)
for (i in seq_len(nb_series))
{
if (parll)
synchronicity::lock(m)
- synchrones[ mi[i], ] = synchrones[ mi[i], ] + ref_series[i,]
- counts[ mi[i] ] = counts[ mi[i] ] + 1 #TODO: remove counts?
+ synchrones[, mi[i] ] = synchrones[, mi[i] ] + ref_series[,i]
+ if (sync_mean)
+ counts[ mi[i] ] = counts[ mi[i] ] + 1
if (parll)
synchronicity::unlock(m)
}
}
- K = nrow(medoids) ; L = ncol(medoids)
+ K = ncol(medoids) ; L = nrow(medoids)
# Use bigmemory (shared==TRUE by default) + synchronicity to fill synchrones in //
# TODO: if size > RAM (not our case), use file-backed big.matrix
- synchrones = bigmemory::big.matrix(nrow=K, ncol=L, type="double", init=0.)
- counts = bigmemory::big.matrix(nrow=K, ncol=1, type="double", init=0)
+ synchrones = bigmemory::big.matrix(nrow=L, ncol=K, type="double", init=0.)
+ if (sync_mean)
+ counts = bigmemory::big.matrix(nrow=K, ncol=1, type="double", init=0)
# synchronicity is only for Linux & MacOS; on Windows: run sequentially
parll = (requireNamespace("synchronicity",quietly=TRUE)
&& parll && Sys.info()['sysname'] != "Windows")
m <- synchronicity::boost.mutex()
m_desc <- synchronicity::describe(m)
synchrones_desc = bigmemory::describe(synchrones)
- counts_desc = bigmemory::describe(counts)
+ if (sync_mean)
+ counts_desc = bigmemory::describe(counts)
medoids_desc = bigmemory::describe(medoids)
cl = parallel::makeCluster(ncores_clust)
- parallel::clusterExport(cl, varlist=c("synchrones_desc","counts_desc","counts",
- "verbose","m_desc","medoids_desc","getRefSeries"), envir=environment())
+ varlist=c("synchrones_desc","sync_mean","m_desc","medoids_desc","getRefSeries")
+ if (sync_mean)
+ varlist = c(varlist, "counts_desc")
+ parallel::clusterExport(cl, varlist, envir=environment())
}
+ if (verbose)
+ {
+ if (verbose)
+ cat(paste("--- Compute ",K," synchrones with ",nb_ref_curves," series\n", sep=""))
+ }
indices_workers = .spreadIndices(seq_len(nb_ref_curves), nb_series_per_chunk)
ignored <-
if (parll)
if (parll)
parallel::stopCluster(cl)
- #TODO: can we avoid this loop? ( synchrones = sweep(synchrones, 1, counts, '/') )
+ if (!sync_mean)
+ return (synchrones)
+
+ #TODO: can we avoid this loop? ( synchrones = sweep(synchrones, 2, counts, '/') )
for (i in seq_len(K))
- synchrones[i,] = synchrones[i,] / counts[i,1]
+ synchrones[,i] = synchrones[,i] / counts[i]
#NOTE: odds for some clusters to be empty? (when series already come from stage 2)
# ...maybe; but let's hope resulting K1' be still quite bigger than K2
- noNA_rows = sapply(seq_len(K), function(i) all(!is.nan(synchrones[i,])))
+ noNA_rows = sapply(seq_len(K), function(i) all(!is.nan(synchrones[,i])))
if (all(noNA_rows))
return (synchrones)
# Else: some clusters are empty, need to slice synchrones
- synchrones[noNA_rows,]
+ bigmemory::as.big.matrix(synchrones[,noNA_rows])
}
#' computeWerDists
#' @return A matrix of size K1 x K1
#'
#' @export
-computeWerDists = function(synchrones, ncores_clust=1,verbose=FALSE,parll=TRUE)
+computeWerDists = function(synchrones, nbytes,endian,ncores_clust=1,verbose=FALSE,parll=TRUE)
{
- if (verbose)
- cat(paste("--- Compute WER dists\n", sep=""))
-
n <- nrow(synchrones)
delta <- ncol(synchrones)
#TODO: automatic tune of all these parameters ? (for other users)
#NOTE: default scalevector == 2^(0:(noctave * nvoice) / nvoice) * s0 (?)
scalevector <- 2^(4:(noctave * nvoice) / nvoice + 1)
#condition: ( log2(s0*w0/(2*pi)) - 1 ) * nvoice + 1.5 >= 1
- s0=2
- w0=2*pi
+ s0 = 2
+ w0 = 2*pi
scaled=FALSE
s0log = as.integer( (log2( s0*w0/(2*pi) ) - 1) * nvoice + 1.5 )
totnoct = noctave + as.integer(s0log/nvoice) + 1
V = V[-1]
pairs = c(pairs, lapply(V, function(v) c(i,v)))
}
-
+
computeSaveCWT = function(index)
{
ts <- scale(ts(synchrones[index,]), center=TRUE, scale=scaled)
res <- sqres / max(Mod(sqres))
#TODO: serializer les CWT, les récupérer via getDataInFile ;
#--> OK, faut juste stocker comme séries simples de taille delta*ncol (53*17519)
- binarize(res, cwt_file, 100, ",", nbytes, endian)
+ binarize(c(as.double(Re(res)),as.double(Im(res))), cwt_file, ncol(res), ",", nbytes, endian)
}
if (parll)
parallel::clusterExport(cl, varlist=c("synchrones_desc","Xwer_dist_desc","totnoct",
"nvoice","w0","s0log","noctave","s0","verbose","getCWT"), envir=environment())
}
-
+
+ if (verbose)
+ {
+ cat(paste("--- Compute WER dists\n", sep=""))
+ # precompute save all CWT........
+ }
#precompute and serialize all CWT
ignored <-
if (parll)
getCWT = function(index)
{
#from cwt_file ...
+ res <- getDataInFile(c(2*index-1,2*index), cwt_file, nbytes, endian)
+ ###############TODO:
}
# Distance between rows i and j
Xwer_dist[i,i] = 0.
}
+ if (verbose)
+ {
+ cat(paste("--- Compute WER dists\n", sep=""))
+ }
ignored <-
if (parll)
parallel::parLapply(cl, pairs, computeDistancesIJ)
}
# Helper function to divide indices into balanced sets
-.spreadIndices = function(indices, nb_per_chunk)
+.spreadIndices = function(indices, nb_per_set)
{
L = length(indices)
- nb_workers = floor( L / nb_per_chunk )
- if (nb_workers == 0)
+ nb_workers = floor( L / nb_per_set )
+ rem = L %% nb_per_set
+ if (nb_workers == 0 || (nb_workers==1 && rem==0))
{
- # L < nb_series_per_chunk, simple case
+ # L <= nb_per_set, simple case
indices_workers = list(indices)
}
else
{
indices_workers = lapply( seq_len(nb_workers), function(i)
- indices[(nb_per_chunk*(i-1)+1):(nb_per_chunk*i)] )
+ indices[(nb_per_set*(i-1)+1):(nb_per_set*i)] )
# Spread the remaining load among the workers
- rem = L %% nb_per_chunk
+ rem = L %% nb_per_set
while (rem > 0)
{
index = rem%%nb_workers + 1