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swishInterxPair <- function(infRepsArray, condition, covariate, pair,
nperms=100, pc=5, fast, quiet=FALSE) {
stopifnot(is.numeric(pair) | is.character(pair) | is.factor(pair))
stopifnot(!anyNA(covariate))
stopifnot(!anyNA(pair))
pair <- as.integer(factor(pair))
if (!all(table(pair, condition) == 1))
stop("'pair' should have a single sample for both levels of 'condition'")
stopifnot(nlevels(covariate) == 2)
if (!all(table(pair, covariate) %in% c(0,2)))
stop("'pair' should be nested within 'covariate'")
dims <- dim(infRepsArray)
out <- getInterxPairStat(infRepsArray, condition, covariate, pair, pc)
stat <- out$stat
group <- out$group
lfcArray <- out$lfcArray
# if fast==1, avoid re-computing the ranks for the permutation distribution
if (fast == 1) {
ranks <- out$ranks
} else {
ranks <- NULL
}
grp1 <- group == levels(group)[1]
grp2 <- group == levels(group)[2]
lfcMat <- apply(lfcArray[,grp2,], c(1,3), mean) -
apply(lfcArray[,grp1,], c(1,3), mean)
# the reported log2FC is the difference in the mean LFC between the two groups
# the median here is taken over inferential replicates
log2FC <- matrixStats::rowMedians(lfcMat)
# the permutation framework is to permute which pairs are in which group
perms <- getPerms(group, nperms)
nperms <- permsNote(perms, nperms)
nulls <- matrix(nrow=dims[1], ncol=nperms)
if (!quiet) message("Generating test statistics over permutations")
for (p in seq_len(nperms)) {
if (!quiet) svMisc::progress(p, max.value=nperms, init=(p==1), gui=FALSE)
nulls[,p] <- getSamStat(lfcArray,
group[perms$perms[p,]],
ranks=ranks)
}
if (!quiet) message("")
list(stat=stat, log2FC=log2FC, nulls=nulls)
}
swishInterx <- function(infRepsArray, condition, covariate,
nperms=100, pc=5, nRandomPairs=30,
quiet=FALSE) {
stopifnot(nlevels(covariate) == 2)
stopifnot(!anyNA(covariate))
if (!all(table(condition, covariate) > 0))
stop("swish with interaction across two variables requires samples for each combination")
dims <- dim(infRepsArray)
tab <- table(condition, covariate)
# if sizes are equal, don't need to double or splice out columns
allEqual <- all(tab[,2] == tab[,1])
# don't have pairs, but instead we use pseudo-pairs multiple times
stats <- matrix(nrow=dims[1], ncol=nRandomPairs)
for (r in seq_len(nRandomPairs)) {
# the easy case: balanced numbers of samples across condition
if (allEqual) {
pair <- getPseudoPair(condition, covariate)
out <- getInterxPairStat(infRepsArray, condition, covariate,
pair, pc)
} else {
# random subsetting to balance groups, then use pseudo pairs
idx <- randomSamplesToRemove(tab, condition, covariate)
pair <- getPseudoPair(condition[-idx], covariate[-idx])
out <- getInterxPairStat(infRepsArray[,-idx,],
condition[-idx], covariate[-idx],
pair, pc)
}
stats[,r] <- out$stat
}
stat <- rowMeans(stats)
# any of the iterations works to define group
# (this is an ordered integer vector of pairs
# across covariate, with condition collapsed as LFCs)
group <- out$group
# log2FC is the difference between condition LFC across covariate groups
log2FC <- getDeltaLFC(infRepsArray, condition, covariate, pc)
# this permutation scheme is different than others in swish
# (and slower) because we reform lfcArray inside the
# permutation loop - necessary because of the random
# pseudo pairs
perms <- getPerms(group, nperms)
nperms <- permsNote(perms, nperms)
nulls <- matrix(nrow=dims[1], ncol=nperms)
if (!quiet) message("Generating test statistics over permutations")
for (p in seq_len(nperms)) {
if (!quiet) svMisc::progress(p, max.value=nperms, init=(p==1), gui=FALSE)
if (allEqual) {
# first draw a pseudo-pairing
pair <- getPseudoPair(condition, covariate)
out <- getInterxPairStat(infRepsArray, condition, covariate,
pair, pc)
} else {
idx <- randomSamplesToRemove(tab, condition, covariate)
pair <- getPseudoPair(condition[-idx], covariate[-idx])
out <- getInterxPairStat(infRepsArray[,-idx,],
condition[-idx], covariate[-idx],
pair, pc)
}
lfcArray <- out$lfcArray
# then permute the pseudo-pairs across covariate
nulls[,p] <- getSamStat(lfcArray,
group[perms$perms[p,]])
}
if (!quiet) message("")
list(stat=stat, log2FC=log2FC, nulls=nulls)
}
getInterxPairStat <- function(infRepsArray, condition, covariate, pair, pc) {
# 'lfcArray' is an array of genes x pair x inf rep
# it is in the order of the pair (1,2,3,...)
lfcArray <- getLog2FCPair(infRepsArray, condition, pair, pc, array=TRUE)
dat <- data.frame(pair, covariate, stringsAsFactors=FALSE)
dat <- dat[!duplicated(dat$pair),]
dat <- dat[order(dat$pair),]
group <- dat$covariate # this is now along 'lfcArray'
stopifnot(length(group) == dim(lfcArray)[2])
# here we perform Wilcoxon rank sum testing of the condition LFCs across group
out <- getSamStat(lfcArray, group, returnRanks=TRUE)
list(stat=out$stat, ranks=out$ranks, group=group, lfcArray=lfcArray)
}
getDeltaLFC <- function(infRepsArray, condition, covariate, pc) {
grp1 <- covariate == levels(covariate)[1]
grp2 <- covariate == levels(covariate)[2]
lfc1 <- getLog2FC(infRepsArray[,grp1,], condition[grp1], pc=pc, array=TRUE)
lfc2 <- getLog2FC(infRepsArray[,grp2,], condition[grp2], pc=pc, array=TRUE)
# the difference in LFC between the two groups, median over inf reps
matrixStats::rowMedians(lfc2 - lfc1)
}
getPseudoPair <- function(condition, covariate) {
pair <- integer(length(condition))
cond1 <- condition == levels(condition)[1]
cond2 <- condition == levels(condition)[2]
pair[cond2] <- seq_len(sum(cond2))
for (i in 1:2) {
grp <- covariate == levels(covariate)[i]
pair[cond1 & grp] <- sample(x=pair[cond2 & grp],
size=sum(cond1 & grp),
replace=FALSE)
}
pair
}
randomSamplesToRemove <- function(tab, condition, covariate) {
cond1 <- condition == levels(condition)[1]
cond2 <- condition == levels(condition)[2]
cov.lvls <- levels(covariate)
idx <- numeric()
for (i in which(tab[,1] != tab[,2])) {
cond1small <- tab[1,i] < tab[2,i]
if (cond1small) {
idx <- c(idx, sample(which(cond2 & covariate == cov.lvls[i]),
tab[2,i] - tab[1,i],
replace=FALSE))
} else {
idx <- c(idx, sample(which(cond1 & covariate == cov.lvls[i]),
tab[1,i] - tab[2,i],
replace=FALSE))
}
}
idx
}
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