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R/setDivergence.R
In divergence: Divergence: Functionality for assessing omics data by divergence with respect to a baseline
Defines functions
computeFeatureSetDigitization
computeFeatureSetBinaryMatrix
findFeatureSetGammaAndSupport
computeFeatureSetSupport
computeSingleFeaturesetBinaryVector
computeSingleFeaturesetSupport
# compute support for a single feature set
computeSingleFeaturesetSupport = function(Mat, features, gamma, beta, distance, j=NULL){
check_gamma_beta(gamma, beta)
features = intersect(rownames(Mat), features)
if(length(features) == 0)
stop("No features available in given data")
Mat = Mat[features, , drop=FALSE]
if(is.null(j))
j = max(floor(gamma * ncol(Mat)), 1)
# get distance to j'th nearest neighbor from each point in x
Mat_Dist = as.matrix(dist(t(Mat), method = distance, diag = FALSE))
xjn = apply(Mat_Dist, 1, function(y){
sort(y, decreasing=FALSE)[j+1]
})
### sel indicate whether a sample is used to build the support
sel = which(xjn <= quantile(xjn, beta))
Radius = xjn[sel]
Centermatrix = Mat[, sel]
Mat_Dist_m2c = Mat_Dist[, sel]
### compare with radius
v = apply(Mat_Dist_m2c,1, function(y){
as.numeric(all(y > Radius))
})
prob = sum(v==1)/length(v)
list(Radius=Radius, Centers=Centermatrix, features=features, alpha=prob, distance=distance)
}
computeSingleFeaturesetBinaryVector = function(Mat, Baseline){
if(! all(Baseline$features %in% rownames(Mat)))
stop("Some features in the support not available in the given data")
Mat = Mat[Baseline$features, , drop=FALSE]
Centers = Baseline$Centers
Radius = Baseline$Radius
distance = Baseline$distance
mn_m <- dim(Mat)
mn_c <- dim(Centers)
Mat_Matrix <- cbind(Centers, Mat)
Mat_Dist <- as.matrix(dist(t(Mat_Matrix), method=distance, diag=FALSE))
### get distance from Mat to Centers
Mat_Dist_m2c <- Mat_Dist[c((mn_c[2]+1):(mn_c[2]+mn_m[2])),c(1:mn_c[2])]
### compare with radius
v <- apply(Mat_Dist_m2c,1, function(y){
as.numeric(all(y > Radius))
})
v
}
computeFeatureSetSupport = function(seMat, FeatureSets, gamma=0.1, beta=0.95, distance="euclidean", verbose=TRUE){
check_gamma_beta(gamma, beta)
featureMat = check_feature_set(FeatureSets)
Mat = get_mat_from_SE(seMat)
Baseline_list = lapply(1:ncol(featureMat), function(j){
features = rownames(featureMat)[which(featureMat[, j] == 1)]
computeSingleFeaturesetSupport(Mat=Mat, features=features, gamma=gamma, beta=beta, distance=distance, j=NULL)
})
names(Baseline_list) = colnames(featureMat)
Support = 1 * t(sapply(Baseline_list, function(B) computeSingleFeaturesetBinaryVector(Mat=Mat, Baseline=B)) == 0)
alpha = mean(sapply(Baseline_list, function(x) x$alpha))
list(Support=Support, Baseline_list=Baseline_list, featureMat=featureMat, alpha=alpha, gamma=gamma, distance=distance)
}
findFeatureSetGammaAndSupport = function(seMat, FeatureSets, gamma=1:9/10, beta=0.95, alpha=0.01, distance="euclidean", verbose=TRUE){
check_gammas_beta(gamma, beta)
check_alpha(alpha)
if(verbose)
message(sprintf("Searching optimal support for alpha threshold=%g\n", alpha))
fgs = list()
optimal = FALSE
Mat = get_mat_from_SE(seMat)
for(i in seq_along(gamma)){
S = computeFeatureSetSupport(
seMat=seMat,
FeatureSets=FeatureSets,
gamma=gamma[i],
beta=beta,
distance=distance,
verbose=verbose)
if(verbose){
message(sprintf("\t[gamma=%g, beta=%g, alpha=%g]\n", gamma[i], beta, S$alpha))
}
fgs[[i]] = S
if(S$alpha <= alpha){
optimal = TRUE
break
}
}
alpha_space = data.frame(gamma=gamma, alpha=NA)
alpha_space$alpha[seq_along(fgs)] = sapply(fgs, function(x) x$alpha)
S$gamma = gamma[i]
S$optimal = optimal
S$alpha_space = alpha_space
S
}
computeFeatureSetBinaryMatrix = function(seMat, Baseline){
Mat = get_mat_from_SE(seMat)
binMat = t(sapply(Baseline$Baseline_list, function(B){
computeSingleFeaturesetBinaryVector(Mat=Mat, Baseline=B)
}))
binMat
}
computeFeatureSetDigitization = function(seMat, seMat.base, FeatureSets,
computeQuantiles=TRUE,
gamma=c(1:9/100, 1:9/10),
beta=0.95,
alpha=0.01,
distance="euclidean",
verbose=TRUE,
findGamma=TRUE,
Groups=NULL,
classes=NULL){
stopifnot(rownames(seMat) == rownames(seMat.base))
if(! is.null(Groups)){
stopifnot(length(Groups) == ncol(seMat))
if(! is.factor(Groups))
Groups = factor(Groups)
if(is.null(classes))
classes = levels(Groups)
}
check_alpha(alpha)
check_gammas_beta(gamma, beta)
featureMat = check_feature_set(FeatureSets)
if(computeQuantiles){
if(verbose)
message(sprintf("Computing quantiles..\n"))
assays(seMat.base)$quantile = getQuantileMat(seMat.base)
assays(seMat)$quantile = getQuantileMat(seMat)
}
if(findGamma){
B = findFeatureSetGammaAndSupport(
seMat=seMat.base,
FeatureSets=FeatureSets,
gamma=gamma, beta=beta, alpha=alpha, distance=distance, verbose=verbose
)
}else{
if(verbose)
message(sprintf("Using gamma=%g\n", gamma[1]))
B = computeFeatureSetSupport(
seMat=seMat.base,
FeatureSets=FeatureSets,
gamma=gamma[1], beta=beta, distance=distance, verbose=verbose
)
}
DMat = computeFeatureSetBinaryMatrix(seMat=seMat, Baseline=B)
baseDMat = computeFeatureSetBinaryMatrix(seMat=seMat.base, Baseline=B)
D = rowMeans(DMat)
N = colSums(DMat)
df = data.frame(feature=rownames(DMat), prob.div=D)
if(! is.null(Groups)){
classDiv = sapply(classes, function(x) rowMeans(DMat[, which(Groups == x)]))
df = data.frame(df, classDiv)
colnames(df) = c("feature", "prob.div", paste("prob.div.", classes, sep=""))
}
list(
Mat.div=DMat,
baseMat.div = baseDMat,
div = data.frame(sample=colnames(DMat), count.div=N),
features.div = df,
Baseline = B,
gamma = B$gamma,
alpha = B$alpha
)
}
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divergence documentation built on Nov. 8, 2020, 8:02 p.m.
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Defines functions computeFeatureSetDigitization computeFeatureSetBinaryMatrix findFeatureSetGammaAndSupport computeFeatureSetSupport computeSingleFeaturesetBinaryVector computeSingleFeaturesetSupport
# compute support for a single feature set
computeSingleFeaturesetSupport = function(Mat, features, gamma, beta, distance, j=NULL){
check_gamma_beta(gamma, beta)
features = intersect(rownames(Mat), features)
if(length(features) == 0)
stop("No features available in given data")
Mat = Mat[features, , drop=FALSE]
if(is.null(j))
j = max(floor(gamma * ncol(Mat)), 1)
# get distance to j'th nearest neighbor from each point in x
Mat_Dist = as.matrix(dist(t(Mat), method = distance, diag = FALSE))
xjn = apply(Mat_Dist, 1, function(y){
sort(y, decreasing=FALSE)[j+1]
})
### sel indicate whether a sample is used to build the support
sel = which(xjn <= quantile(xjn, beta))
Radius = xjn[sel]
Centermatrix = Mat[, sel]
Mat_Dist_m2c = Mat_Dist[, sel]
### compare with radius
v = apply(Mat_Dist_m2c,1, function(y){
as.numeric(all(y > Radius))
})
prob = sum(v==1)/length(v)
list(Radius=Radius, Centers=Centermatrix, features=features, alpha=prob, distance=distance)
}
computeSingleFeaturesetBinaryVector = function(Mat, Baseline){
if(! all(Baseline$features %in% rownames(Mat)))
stop("Some features in the support not available in the given data")
Mat = Mat[Baseline$features, , drop=FALSE]
Centers = Baseline$Centers
Radius = Baseline$Radius
distance = Baseline$distance
mn_m <- dim(Mat)
mn_c <- dim(Centers)
Mat_Matrix <- cbind(Centers, Mat)
Mat_Dist <- as.matrix(dist(t(Mat_Matrix), method=distance, diag=FALSE))
### get distance from Mat to Centers
Mat_Dist_m2c <- Mat_Dist[c((mn_c[2]+1):(mn_c[2]+mn_m[2])),c(1:mn_c[2])]
### compare with radius
v <- apply(Mat_Dist_m2c,1, function(y){
as.numeric(all(y > Radius))
})
v
}
computeFeatureSetSupport = function(seMat, FeatureSets, gamma=0.1, beta=0.95, distance="euclidean", verbose=TRUE){
check_gamma_beta(gamma, beta)
featureMat = check_feature_set(FeatureSets)
Mat = get_mat_from_SE(seMat)
Baseline_list = lapply(1:ncol(featureMat), function(j){
features = rownames(featureMat)[which(featureMat[, j] == 1)]
computeSingleFeaturesetSupport(Mat=Mat, features=features, gamma=gamma, beta=beta, distance=distance, j=NULL)
})
names(Baseline_list) = colnames(featureMat)
Support = 1 * t(sapply(Baseline_list, function(B) computeSingleFeaturesetBinaryVector(Mat=Mat, Baseline=B)) == 0)
alpha = mean(sapply(Baseline_list, function(x) x$alpha))
list(Support=Support, Baseline_list=Baseline_list, featureMat=featureMat, alpha=alpha, gamma=gamma, distance=distance)
}
findFeatureSetGammaAndSupport = function(seMat, FeatureSets, gamma=1:9/10, beta=0.95, alpha=0.01, distance="euclidean", verbose=TRUE){
check_gammas_beta(gamma, beta)
check_alpha(alpha)
if(verbose)
message(sprintf("Searching optimal support for alpha threshold=%g\n", alpha))
fgs = list()
optimal = FALSE
Mat = get_mat_from_SE(seMat)
for(i in seq_along(gamma)){
S = computeFeatureSetSupport(
seMat=seMat,
FeatureSets=FeatureSets,
gamma=gamma[i],
beta=beta,
distance=distance,
verbose=verbose)
if(verbose){
message(sprintf("\t[gamma=%g, beta=%g, alpha=%g]\n", gamma[i], beta, S$alpha))
}
fgs[[i]] = S
if(S$alpha <= alpha){
optimal = TRUE
break
}
}
alpha_space = data.frame(gamma=gamma, alpha=NA)
alpha_space$alpha[seq_along(fgs)] = sapply(fgs, function(x) x$alpha)
S$gamma = gamma[i]
S$optimal = optimal
S$alpha_space = alpha_space
S
}
computeFeatureSetBinaryMatrix = function(seMat, Baseline){
Mat = get_mat_from_SE(seMat)
binMat = t(sapply(Baseline$Baseline_list, function(B){
computeSingleFeaturesetBinaryVector(Mat=Mat, Baseline=B)
}))
binMat
}
computeFeatureSetDigitization = function(seMat, seMat.base, FeatureSets,
computeQuantiles=TRUE,
gamma=c(1:9/100, 1:9/10),
beta=0.95,
alpha=0.01,
distance="euclidean",
verbose=TRUE,
findGamma=TRUE,
Groups=NULL,
classes=NULL){
stopifnot(rownames(seMat) == rownames(seMat.base))
if(! is.null(Groups)){
stopifnot(length(Groups) == ncol(seMat))
if(! is.factor(Groups))
Groups = factor(Groups)
if(is.null(classes))
classes = levels(Groups)
}
check_alpha(alpha)
check_gammas_beta(gamma, beta)
featureMat = check_feature_set(FeatureSets)
if(computeQuantiles){
if(verbose)
message(sprintf("Computing quantiles..\n"))
assays(seMat.base)$quantile = getQuantileMat(seMat.base)
assays(seMat)$quantile = getQuantileMat(seMat)
}
if(findGamma){
B = findFeatureSetGammaAndSupport(
seMat=seMat.base,
FeatureSets=FeatureSets,
gamma=gamma, beta=beta, alpha=alpha, distance=distance, verbose=verbose
)
}else{
if(verbose)
message(sprintf("Using gamma=%g\n", gamma[1]))
B = computeFeatureSetSupport(
seMat=seMat.base,
FeatureSets=FeatureSets,
gamma=gamma[1], beta=beta, distance=distance, verbose=verbose
)
}
DMat = computeFeatureSetBinaryMatrix(seMat=seMat, Baseline=B)
baseDMat = computeFeatureSetBinaryMatrix(seMat=seMat.base, Baseline=B)
D = rowMeans(DMat)
N = colSums(DMat)
df = data.frame(feature=rownames(DMat), prob.div=D)
if(! is.null(Groups)){
classDiv = sapply(classes, function(x) rowMeans(DMat[, which(Groups == x)]))
df = data.frame(df, classDiv)
colnames(df) = c("feature", "prob.div", paste("prob.div.", classes, sep=""))
}
list(
Mat.div=DMat,
baseMat.div = baseDMat,
div = data.frame(sample=colnames(DMat), count.div=N),
features.div = df,
Baseline = B,
gamma = B$gamma,
alpha = B$alpha
)
}
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