[epclust.git] / epclust / R / computeWerDists.R

#' computeWerDists
#'
#' Compute the WER distances between the series at specified indices, which are
#' obtaind by \code{getSeries(indices)}
#'
#' @param indices Range of series indices to cluster
#' @inheritParams claws
#' @inheritParams computeSynchrones
#'
#' @return A distances matrix of size K x K where K == length(indices)
#'
#' @export
computeWerDists <- function(indices, getSeries, nb_series_per_chunk, smooth_lvl, nvoice,
	nbytes, endian, ncores_clust=3, verbose=FALSE, parll=TRUE)
{
	n <- length(indices)
	L <- length(getSeries(1)) #TODO: not very neat way to get L
	noctave <- ceiling(log2(L)) #min power of 2 to cover serie range
	# Since a CWT contains noctave*nvoice complex series, we deduce the number of CWT to
	# retrieve/put in one chunk.
	nb_cwt_per_chunk <- max(1, floor(nb_series_per_chunk / (nvoice*noctave*2)))

	# Initialize result as a square big.matrix of size 'number of medoids'
	Xwer_dist <- bigmemory::big.matrix(nrow=n, ncol=n, type="double")

	cwt_file <- tempfile(pattern="epclust_cwt.bin_")
	# Compute the getSeries(indices) CWT, and store the results in the binary file
	computeSaveCWT <- function(indices)
	{
		if (parll)
		{
			# parallel workers start with an empty environment
			require("epclust", quietly=TRUE)
		}

		# Obtain CWT as big vectors of real part + imaginary part (concatenate)
		ts_cwt <- sapply(indices, function(i) {
			ts <- scale(ts(getSeries(i)), center=TRUE, scale=FALSE)
			ts_cwt <- Rwave::cwt(ts, noctave, nvoice, w0=2*pi, twoD=TRUE, plot=FALSE)
			c( as.double(Re(ts_cwt)),as.double(Im(ts_cwt)) )
		})

		# Serialization
		binarize(ts_cwt, cwt_file, nb_cwt_per_chunk, ",", nbytes, endian)
	}

	# Function to retrieve a synchrone CWT from (binary) file
	getCWT <- function(index, L)
	{
		flat_cwt <- getDataInFile(index, cwt_file, nbytes, endian)
		cwt_length <- length(flat_cwt) / 2
		re_part <- as.matrix(flat_cwt[1:cwt_length], nrow=L)
		im_part <- as.matrix(flat_cwt[(cwt_length+1):(2*cwt_length)], nrow=L)
		re_part + 1i * im_part
	}

	# Compute distance between columns i and j for j>i
	computeDistances <- function(i)
	{
		if (parll)
		{
			# parallel workers start with an empty environment
			require("epclust", quietly=TRUE)
			Xwer_dist <- bigmemory::attach.big.matrix(Xwer_dist_desc)
		}

		if (verbose && !parll)
			cat(paste("   Distances from ",i," to ",i+1,"...",n,"\n", sep=""))

		# Get CWT of column i, and run computations for columns j>i
		cwt_i <- getCWT(i, L)
		WX  <- filterMA(Mod(cwt_i * Conj(cwt_i)), smooth_lvl)

		for (j in (i+1):n)
		{
			cwt_j <- getCWT(j, L)

			# Compute the ratio of integrals formula 5.6 for WER^2
			# in https://arxiv.org/abs/1101.4744v2 paragraph 5.3
			num <- filterMA(Mod(cwt_i * Conj(cwt_j)), smooth_lvl)
			WY <- filterMA(Mod(cwt_j * Conj(cwt_j)), smooth_lvl)
			wer2 <- sum(colSums(num)^2) / sum(colSums(WX) * colSums(WY))

			Xwer_dist[i,j] <- sqrt(L * ncol(cwt_i) * (1 - wer2))
			Xwer_dist[j,i] <- Xwer_dist[i,j]
		}
		Xwer_dist[i,i] <- 0.
	}

	if (parll)
	{
		# outfile=="" to see stderr/stdout on terminal
		cl <-
			if (verbose)
				parallel::makeCluster(ncores_clust, outfile="")
			else
				parallel::makeCluster(ncores_clust)
		Xwer_dist_desc <- bigmemory::describe(Xwer_dist)
		parallel::clusterExport(cl, varlist=c("parll","nb_cwt_per_chunk","n","L",
			"Xwer_dist_desc","noctave","nvoice","getCWT"), envir=environment())
	}

	if (verbose)
		cat(paste("--- Precompute and serialize synchrones CWT\n", sep=""))

	# Split indices by packets of length at most nb_cwt_per_chunk
	indices_cwt <- .splitIndices(seq_len(n), nb_cwt_per_chunk)
	ignored <-
		if (parll)
			parallel::parLapply(cl, indices_cwt, computeSaveCWT)
		else
			lapply(indices_cwt, computeSaveCWT)

	if (verbose)
		cat(paste("--- Compute WER distances\n", sep=""))

	ignored <-
		if (parll)
			parallel::parLapply(cl, seq_len(n-1), computeDistances)
		else
			lapply(seq_len(n-1), computeDistances)
	Xwer_dist[n,n] <- 0.

	if (parll)
		parallel::stopCluster(cl)

	unlink(cwt_file) #remove binary file

	Xwer_dist[,] #~small matrix K1 x K1
}
Commit	Line	Data
40f12a2f BA	1	#' computeWerDists
40f12a2f BA	2	#'
3fb6e823 BA	3	#' Compute the WER distances between the series at specified indices, which are
3fb6e823 BA	4	#' obtaind by \code{getSeries(indices)}
40f12a2f	5	#'
3c5a4b08	6	#' @param indices Range of series indices to cluster
40f12a2f	7	#' @inheritParams claws
3c5a4b08	8	#' @inheritParams computeSynchrones
40f12a2f	9	#'
3c5a4b08	10	#' @return A distances matrix of size K x K where K == length(indices)
40f12a2f BA	11	#'
40f12a2f BA	12	#' @export
282342ba	13	computeWerDists <- function(indices, getSeries, nb_series_per_chunk, smooth_lvl, nvoice,
3fb6e823	14	nbytes, endian, ncores_clust=3, verbose=FALSE, parll=TRUE)
40f12a2f	15	{
3c5a4b08	16	n <- length(indices)
282342ba BA	17	L <- length(getSeries(1)) #TODO: not very neat way to get L
282342ba BA	18	noctave <- ceiling(log2(L)) #min power of 2 to cover serie range
3c5a4b08 BA	19	# Since a CWT contains noctave*nvoice complex series, we deduce the number of CWT to
3c5a4b08 BA	20	# retrieve/put in one chunk.
282342ba	21	nb_cwt_per_chunk <- max(1, floor(nb_series_per_chunk / (nvoicenoctave2)))
40f12a2f	22
3c5a4b08	23	# Initialize result as a square big.matrix of size 'number of medoids'
40f12a2f BA	24	Xwer_dist <- bigmemory::big.matrix(nrow=n, ncol=n, type="double")
40f12a2f BA	25
282342ba	26	cwt_file <- tempfile(pattern="epclust_cwt.bin_")
3c5a4b08	27	# Compute the getSeries(indices) CWT, and store the results in the binary file
282342ba	28	computeSaveCWT <- function(indices)
40f12a2f BA	29	{
	30	if (parll)
	31	{
3fb6e823	32	# parallel workers start with an empty environment
40f12a2f	33	require("epclust", quietly=TRUE)
40f12a2f BA	34	}
	35
	36	# Obtain CWT as big vectors of real part + imaginary part (concatenate)
	37	ts_cwt <- sapply(indices, function(i) {
3c5a4b08	38	ts <- scale(ts(getSeries(i)), center=TRUE, scale=FALSE)
40f12a2f BA	39	ts_cwt <- Rwave::cwt(ts, noctave, nvoice, w0=2*pi, twoD=TRUE, plot=FALSE)
	40	c( as.double(Re(ts_cwt)),as.double(Im(ts_cwt)) )
	41	})
	42
	43	# Serialization
3c5a4b08	44	binarize(ts_cwt, cwt_file, nb_cwt_per_chunk, ",", nbytes, endian)
40f12a2f BA	45	}
40f12a2f BA	46
40f12a2f	47	# Function to retrieve a synchrone CWT from (binary) file
282342ba	48	getCWT <- function(index, L)
40f12a2f BA	49	{
40f12a2f BA	50	flat_cwt <- getDataInFile(index, cwt_file, nbytes, endian)
282342ba BA	51	cwt_length <- length(flat_cwt) / 2
	52	re_part <- as.matrix(flat_cwt[1:cwt_length], nrow=L)
	53	im_part <- as.matrix(flat_cwt[(cwt_length+1):(2*cwt_length)], nrow=L)
40f12a2f BA	54	re_part + 1i * im_part
	55	}
	56
282342ba BA	57	# Compute distance between columns i and j for j>i
282342ba BA	58	computeDistances <- function(i)
40f12a2f BA	59	{
	60	if (parll)
	61	{
	62	# parallel workers start with an empty environment
40f12a2f	63	require("epclust", quietly=TRUE)
40f12a2f BA	64	Xwer_dist <- bigmemory::attach.big.matrix(Xwer_dist_desc)
	65	}
	66
282342ba BA	67	if (verbose && !parll)
282342ba BA	68	cat(paste(" Distances from ",i," to ",i+1,"...",n,"\n", sep=""))
40f12a2f	69
282342ba	70	# Get CWT of column i, and run computations for columns j>i
3c5a4b08	71	cwt_i <- getCWT(i, L)
282342ba BA	72	WX <- filterMA(Mod(cwt_i * Conj(cwt_i)), smooth_lvl)
	73
	74	for (j in (i+1):n)
	75	{
	76	cwt_j <- getCWT(j, L)
40f12a2f	77
282342ba	78	# Compute the ratio of integrals formula 5.6 for WER^2
3fb6e823	79	# in https://arxiv.org/abs/1101.4744v2 paragraph 5.3
282342ba BA	80	num <- filterMA(Mod(cwt_i * Conj(cwt_j)), smooth_lvl)
	81	WY <- filterMA(Mod(cwt_j * Conj(cwt_j)), smooth_lvl)
	82	wer2 <- sum(colSums(num)^2) / sum(colSums(WX) * colSums(WY))
40f12a2f	83
282342ba BA	84	Xwer_dist[i,j] <- sqrt(L * ncol(cwt_i) * (1 - wer2))
	85	Xwer_dist[j,i] <- Xwer_dist[i,j]
	86	}
40f12a2f BA	87	Xwer_dist[i,i] <- 0.
	88	}
	89
282342ba BA	90	if (parll)
	91	{
	92	# outfile=="" to see stderr/stdout on terminal
3fb6e823 BA	93	cl <-
	94	if (verbose)
	95	parallel::makeCluster(ncores_clust, outfile="")
	96	else
	97	parallel::makeCluster(ncores_clust)
282342ba BA	98	Xwer_dist_desc <- bigmemory::describe(Xwer_dist)
	99	parallel::clusterExport(cl, varlist=c("parll","nb_cwt_per_chunk","n","L",
	100	"Xwer_dist_desc","noctave","nvoice","getCWT"), envir=environment())
	101	}
	102
	103	if (verbose)
	104	cat(paste("--- Precompute and serialize synchrones CWT\n", sep=""))
	105
	106	# Split indices by packets of length at most nb_cwt_per_chunk
	107	indices_cwt <- .splitIndices(seq_len(n), nb_cwt_per_chunk)
	108	ignored <-
	109	if (parll)
	110	parallel::parLapply(cl, indices_cwt, computeSaveCWT)
	111	else
	112	lapply(indices_cwt, computeSaveCWT)
	113
40f12a2f BA	114	if (verbose)
	115	cat(paste("--- Compute WER distances\n", sep=""))
	116
	117	ignored <-
	118	if (parll)
282342ba	119	parallel::parLapply(cl, seq_len(n-1), computeDistances)
40f12a2f	120	else
282342ba BA	121	lapply(seq_len(n-1), computeDistances)
282342ba BA	122	Xwer_dist[n,n] <- 0.
40f12a2f BA	123
	124	if (parll)
	125	parallel::stopCluster(cl)
	126
282342ba	127	unlink(cwt_file) #remove binary file
40f12a2f	128
40f12a2f BA	129	Xwer_dist[,] #~small matrix K1 x K1
40f12a2f BA	130	}