Nothing
R/matalign.R
In motifStack: Plot stacked logos for single or multiple DNA, RNA and amino acid sequence
Defines functions
Eval2Pval
getEval
getDistance
traceBackGlobal
traceBackLocal
dpGlobal
dpLocal
getALLRscoreFromCounts
calF
calI
condenseByGroup
getScore
compare2profiles
compareProfiles
matalign
Documented in
calF
calI
compare2profiles
compareProfiles
dpGlobal
dpLocal
getALLRscoreFromCounts
getDistance
getScore
matalign
traceBackGlobal
traceBackLocal
#' Matrix Aligner
#' @description Matrix Aligner is modified from Matalign-v4a.
#' Matalign-v4a is a program to compare two positional specific matrices.
#' The author of Matalign-v4a is Ting Wang and Gary Stormo.
#' @param pcms A list of \link{pcm}
#' @param method Alignment method. "Smith-Waterman" or "Needleman-Wunsch".
#' Default is "Smith-Waterma"
#' @param pseudo pseudocount
#' @param revcomp Check reverseComplement or not.
#' @param ... Not use.
#' @return A data frame with alignment information. The column names
#' are motif1, motif2, alignmentScore, startPos1, startPos2, endPos1, endPos2,
#' alignmentLength.
#' @export
#' @importFrom utils combn
#' @examples
#' if(interactive() || Sys.getenv("USER")=="jianhongou"){
#' fp <- system.file("extdata", package="motifStack")
#' fs <- dir(fp, "pcm$")
#' pcms <- importMatrix(file.path(fp, fs), format="pcm")
#' matalign(pcms)
#' }
matalign <- function(pcms,
method=c("Smith-Waterman", "Needleman-Wunsch"),
pseudo=1,
revcomp=TRUE,
...){
method <- match.arg(method,
choices = c("Smith-Waterman", "Needleman-Wunsch"))
stopifnot(is.numeric(pseudo))
stopifnot(is.list(pcms))
if(length(names(pcms))!=length(pcms))
names(pcms) <- paste0("M", seq_along(pcms))
pcms <- mapply(pcms, names(pcms), FUN=function(.ele, .name){
if(is(.ele, "pcm")){
return(.ele)
}
if(is(.ele, "pfm")){
return(pfm2pcm(.ele))
}
if(is(.ele, "matrix") || is(.ele, "data.frame")){
cols <- colSums(.ele)
if(all(abs(1 - cols) < 0.01)){
.ele <- new("pfm", name=.name, mat=.ele)
return(pfm2pcm(.ele))
}
if(all(cols>=1) && all(cols==round(cols))){
return(new("pcm", name=.name, mat=.ele))
}
}
stop("motifs must be pcms")
}, SIMPLIFY = FALSE)
stopifnot("pcms must be a list of pcm object" = is.list(pcms))
null <- lapply(pcms, function(.ele) if(!is(.ele, "pcm")){
stop("pcms must be a list of pcm object.")
})
n <- vapply(pcms, FUN = function(.ele) .ele@name,
FUN.VALUE = "a", USE.NAMES = FALSE)
alphab <- vapply(pcms, function(.ele) .ele@alphabet=="RNA", FUN.VALUE = TRUE)
if(any(alphab)&revcomp){
message("The input is RNA motif.
The reverse complementation alignment will be turn off.
To avoid this message, please set revcomp=FALSE")
revcomp <- FALSE
}
stopifnot("There is duplicated motif names"=!duplicated(n))
names(pcms) <- n
cmb <- combn(n, m = 2, simplify = FALSE)
align <- lapply(cmb, FUN=function(.ele){
compareProfiles(pcms[[.ele[1]]], pcms[[.ele[2]]],
pseudo=pseudo, revcomp=revcomp)
})
align <- do.call(rbind, align)
align <- cbind(do.call(rbind, cmb), align[, -(2:3)])
colnames(align) <- c("motif1", "motif2", "alignmentScore",
"startPos1", "startPos2", "endPos1", "endPos2",
"alignmentLength", "P_value",
"distance", 'alignedDist',
"direction")[seq.int(ncol(align))]
return(align)
}
#' comapre w pcm
#' @description compare two pcm objects
#' @param pcm1,pcm2 object of pcm
#' @param method Alignment method. "Smith-Waterman" or "Needleman-Wunsch".
#' Default is "Smith-Waterma"
#' @param pseudo pseudocount
#' @param revcomp Check reverseComplement or not.
#' @return a list with names: motif1, motif2, alignmentScore,
#' startPos1, startPos2, endPos1, endPos2, alignmentLength.
compareProfiles <- function(pcm1, pcm2,
method=c("Smith-Waterman", "Needleman-Wunsch"),
pseudo=1,
revcomp=TRUE){
method <- match.arg(method,
choices = c("Smith-Waterman", "Needleman-Wunsch"))
hspF <- compare2profiles(pcm1, pcm2, method, pseudo)
if(!(pcm1@alphabet %in% c("DNA", "RNA")) || !revcomp){
hspF$direction <- "Forward"
return(hspF)
}
hspR <- compare2profiles(pcm1, matrixReverseComplement(pcm2),
method, pseudo)
if(hspF$score >= hspR$score){
hspF$direction <- "Forward"
return(hspF)
}else{
hspR$direction <- "Reverse"
return(hspR)
}
}
#' compare two profiles
#' @description compare two pcm object
#' @param pcm1,pcm2 object of pcm
#' @param method Alignment method. "Smith-Waterman" or "Needleman-Wunsch".
#' Default is "Smith-Waterma"
#' @param pseudo pseudocount
#' @return a list with names: motif1, motif2, alignmentScore,
#' startPos1, startPos2, endPos1, endPos2, alignmentLength.
compare2profiles <- function(pcm1, pcm2,
method = c("Smith-Waterman",
"Needleman-Wunsch"),
pseudo=1
){
method <- match.arg(method,
choices = c("Smith-Waterman", "Needleman-Wunsch"))
profile1 <- pcm1@mat
profile2 <- pcm2@mat
width1 <- ncol(profile1)
width2 <- ncol(profile2)
score <- getScore(pcm1, pcm2, pseudo)
if(method == "Needleman-Wunsch"){
dpScore <- dpGlobal(score, width1, width2)
hsp <- traceBackGlobal(dpScore, score, width1, width2)
}else{
dpScore <- dpLocal(score, width1, width2)
hsp <- traceBackLocal(dpScore, score, width1, width2)
}
dist <- getDistance(hsp, count1 = profile1, count2 = profile2,
P1 = pcm1@background, P2 = pcm2@background,
pseudo = pseudo)
hsp$distance <- dist[1]
hsp$alignedDist <- dist[2]
return(hsp)
}
#' Calculate pair_wise position score
#' @param pcm1,pcm2 object of pcm
#' @param pseudo pseudocount
#' @return A score matrix with nrow of ncol of pcm1
#' and ncol of ncol of pcm2.
getScore <- function(pcm1, pcm2, pseudo=1){
stopifnot("input is not pcm object"=is(pcm1, "pcm"))
stopifnot("input is not pcm object"=is(pcm2, "pcm"))
profile1 <- pcm1@mat
profile2 <- pcm2@mat
P1 <- pcm1@background
P2 <- pcm2@background
isAA <- pcm1@alphabet=="AA" && pcm2@alphabet=="AA"
score <- matrix(0,
nrow = ncol(profile1),
ncol = ncol(profile2))
for(i in seq.int(ncol(profile1))){
for(j in seq.int(ncol(profile2))){
if(isAA){##condense AA by chemical characteristics
score[i, j] <-
getALLRscoreFromCounts(condenseByGroup(profile1[, i]),
condenseByGroup(profile2[, j]),
condenseByGroup(P1),
condenseByGroup(P2), pseudo)
}else{
score[i, j] <-
getALLRscoreFromCounts(profile1[, i], profile2[, j],
P1, P2, pseudo)
}
}
}
return(score)
}
condenseByGroup <- function(x,
group=list(A=c("G", "A", "V", "L", "I"),
S=c("S", "C", "U", "T", "M"),
P=c("P"),
F=c("F", "Y", "W"),
H=c("H", "K", "R"),
D=c("D", "E", "N", "Q"))){
stopifnot(all(names(x) %in% unlist(group)))
stopifnot(is.list(group))
stopifnot(length(names(group))>0)
vapply(group, FUN = function(.ele){
sum(x[.ele], na.rm = TRUE)
}, FUN.VALUE = 0.0)
}
#' calculate I'
#' @param freq1 position frequence for matrix 1 position j
#' @param freq2 position frequence for matrix 2 position j
#' @param P background of profile1
#' @return numeric(1)
calI <- function(freq1, freq2, P){
sum(freq2*log(freq1/P)/log(2))
}
#' calculate frequence
#' @param count position counts
#' @param P background probility
#' @param pseudo pseudocount
#' @return numeric(1)
calF <- function(count,
P=rep(1/length(count), length(count)),
pseudo=1){
total <- sum(count)
f <- (count + P*pseudo)/(total+pseudo)
return(f)
}
#' calculate ALLR from counts
#' @param count1,count2 count in position j for matrix 1 or 2
#' @param P1,P2 background for matrix 1 or 2
#' @param pseudo pseudocount
#' @return numeric(1) of ALLR
getALLRscoreFromCounts <- function(count1, count2, P1, P2, pseudo){
freq1 <- calF(count1, P1, pseudo)
freq2 <- calF(count2, P2, pseudo)
I1 <- calI(freq1, freq2, P1)
I2 <- calI(freq2, freq1, P2)
total1 <- sum(count1)
total2 <- sum(count2)
score <- (I1*total2 + I2*total1)/(total1+total2)
return(score)
}
#' Dynamic programming function, local version
#' @param score ALLR scores, m x n matrix
#' @param m,n matrix width
#' @return score matrix
dpLocal <- function(score, m, n){
s <- 0
DP <- matrix(0, nrow = m, ncol = n)
DP[score[, 1]>0, 1] <- score[score[, 1]>0, 1]
DP[1, score[1, ]>0] <- score[1, score[1, ]>0]
for(i in seq.int(m)[-1]){
for(j in seq.int(n)[-1]){
s <- DP[i-1, j-1] + score[i, j]
DP[i, j] <- ifelse(s>0, s, 0)
}
}
return(DP)
}
#' Global alignment version
#' @param score ALLR scores, m x n matrix
#' @param m,n matrix width
#' @return score matrix
dpGlobal <- function(score, m, n){
s <- 0
DP <- matrix(0, nrow = m, ncol = n)
DP[, 1] <- score[, 1]
DP[1, ] <- score[1, ]
for(i in seq.int(m)[-1]){
for(j in seq.int(n)[-1]){
s <- DP[i-1, j-1] + score[i, j]
DP[i, j] <- s
}
}
return(DP)
}
#' traceback local
#' @param dpScore Dynamic programming score matrix
#' @param score ALLR scores, m x n matrix
#' @param m,n matrix width
#' @return a data.frame
traceBackLocal <- function(dpScore, score, m, n){
max <- max(dpScore)
maxpos <- which.max(dpScore)
maxpos <- maxpos[length(maxpos)]
j <- j_end <- ceiling(maxpos/m)
i <- i_end <- maxpos - m*(j_end - 1)
while(i>1 && j>1){
if(dpScore[i, j]>0){
i <- i-1
j <- j-1
}else{
i <- i+1
j <- j+1
break()
}
}
i_start <- i
j_start <- j
eval <- getEval(max, m, n)
pval <- Eval2Pval(eval)
return(data.frame(score=max,
width1=m,
width2=n,
i_start=i_start,
j_start=j_start,
i_end=i_end,
j_end=j_end,
length=i_end - i_start + 1,
P_value=pval))
}
#' traceback global
#' @param dpScore Dynamic programming score
#' @param score ALLR scores
#' @param m,n matrix width
#' @return a data.frame
traceBackGlobal <- function(dpScore, score, m, n){
max <- dpScore[m, n]
i_end <- m
j_end <- n
for(i in seq.int(m)){
if(dpScore[i, n]>=max){
max <- dpScore[i, n]
i_end <- i
j_end <- n
}
}
for(j in seq.int(n)){
if(dpScore[m, j]>=max){
max <- dpScore[m, j]
i_end <- m
j_end <- j
}
}
i <- i_end
j <- j_end
while(i>1 && j>1){
i <- i-1
j <- j-1
}
i_start <- i
j_start <- j
eval <- getEval(max, m, n)
pval <- Eval2Pval(eval)
return(data.frame(score=max,
width1=m,
width2=n,
i_start=i_start,
j_start=j_start,
i_end=i_end,
j_end=j_end,
length=i_end - i_start + 1,
P_value=pval))
}
#' Calculate distances between two profiles
#' @param hsp output of traceBack function
#' @param count1,count2 motif profile 1 or 2
#' @param P1,P2 background of profile 1 or 2
#' @param pseudo pseudocount
#' @return full distance and aligned distance.
getDistance <- function(hsp, count1, count2,
P1, P2, pseudo){
full1 <- sum(
apply(count1, 2, function(.ele)
getALLRscoreFromCounts(count1 = .ele, count2 = .ele,
P1=P1, P2=P1, pseudo = pseudo))
)
if(hsp$i_start<=hsp$i_end){
aligned1 <- sum(
apply(count1[, hsp$i_start:hsp$i_end, drop=FALSE], 2, function(.ele)
getALLRscoreFromCounts(count1 = .ele, count2 = .ele,
P1=P1, P2=P1, pseudo = pseudo))
)
}else{
aligned1 <- 0
}
full2 <- sum(
apply(count2, 2, function(.ele)
getALLRscoreFromCounts(count1 = .ele, count2 = .ele,
P1=P2, P2=P2, pseudo = pseudo))
)
if(hsp$i_start<=hsp$i_end){
aligned2 <- sum(
apply(count2[, hsp$j_start:hsp$j_end, drop=FALSE], 2, function(.ele)
getALLRscoreFromCounts(count1 = .ele, count2 = .ele,
P1=P2, P2=P2, pseudo = pseudo))
)
}else{
aligned2 <- 0
}
return(c(
dist1 = full1 + full2 - 2*hsp$score,
dist2 = aligned1 + aligned2 - 2*hsp$score
))
}
getEval <- function(alignmentScore, m, n){
Lambda <- 0.02094
K <- 0.26062
H <- 3.25810
K * m * n * exp (-Lambda*(alignmentScore*100))
}
Eval2Pval <- function(e){
1 - exp(-e)
}
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Defines functions Eval2Pval getEval getDistance traceBackGlobal traceBackLocal dpGlobal dpLocal getALLRscoreFromCounts calF calI condenseByGroup getScore compare2profiles compareProfiles matalign
Documented in calF calI compare2profiles compareProfiles dpGlobal dpLocal getALLRscoreFromCounts getDistance getScore matalign traceBackGlobal traceBackLocal
#' Matrix Aligner
#' @description Matrix Aligner is modified from Matalign-v4a.
#' Matalign-v4a is a program to compare two positional specific matrices.
#' The author of Matalign-v4a is Ting Wang and Gary Stormo.
#' @param pcms A list of \link{pcm}
#' @param method Alignment method. "Smith-Waterman" or "Needleman-Wunsch".
#' Default is "Smith-Waterma"
#' @param pseudo pseudocount
#' @param revcomp Check reverseComplement or not.
#' @param ... Not use.
#' @return A data frame with alignment information. The column names
#' are motif1, motif2, alignmentScore, startPos1, startPos2, endPos1, endPos2,
#' alignmentLength.
#' @export
#' @importFrom utils combn
#' @examples
#' if(interactive() || Sys.getenv("USER")=="jianhongou"){
#' fp <- system.file("extdata", package="motifStack")
#' fs <- dir(fp, "pcm$")
#' pcms <- importMatrix(file.path(fp, fs), format="pcm")
#' matalign(pcms)
#' }
matalign <- function(pcms,
method=c("Smith-Waterman", "Needleman-Wunsch"),
pseudo=1,
revcomp=TRUE,
...){
method <- match.arg(method,
choices = c("Smith-Waterman", "Needleman-Wunsch"))
stopifnot(is.numeric(pseudo))
stopifnot(is.list(pcms))
if(length(names(pcms))!=length(pcms))
names(pcms) <- paste0("M", seq_along(pcms))
pcms <- mapply(pcms, names(pcms), FUN=function(.ele, .name){
if(is(.ele, "pcm")){
return(.ele)
}
if(is(.ele, "pfm")){
return(pfm2pcm(.ele))
}
if(is(.ele, "matrix") || is(.ele, "data.frame")){
cols <- colSums(.ele)
if(all(abs(1 - cols) < 0.01)){
.ele <- new("pfm", name=.name, mat=.ele)
return(pfm2pcm(.ele))
}
if(all(cols>=1) && all(cols==round(cols))){
return(new("pcm", name=.name, mat=.ele))
}
}
stop("motifs must be pcms")
}, SIMPLIFY = FALSE)
stopifnot("pcms must be a list of pcm object" = is.list(pcms))
null <- lapply(pcms, function(.ele) if(!is(.ele, "pcm")){
stop("pcms must be a list of pcm object.")
})
n <- vapply(pcms, FUN = function(.ele) .ele@name,
FUN.VALUE = "a", USE.NAMES = FALSE)
alphab <- vapply(pcms, function(.ele) .ele@alphabet=="RNA", FUN.VALUE = TRUE)
if(any(alphab)&revcomp){
message("The input is RNA motif.
The reverse complementation alignment will be turn off.
To avoid this message, please set revcomp=FALSE")
revcomp <- FALSE
}
stopifnot("There is duplicated motif names"=!duplicated(n))
names(pcms) <- n
cmb <- combn(n, m = 2, simplify = FALSE)
align <- lapply(cmb, FUN=function(.ele){
compareProfiles(pcms[[.ele[1]]], pcms[[.ele[2]]],
pseudo=pseudo, revcomp=revcomp)
})
align <- do.call(rbind, align)
align <- cbind(do.call(rbind, cmb), align[, -(2:3)])
colnames(align) <- c("motif1", "motif2", "alignmentScore",
"startPos1", "startPos2", "endPos1", "endPos2",
"alignmentLength", "P_value",
"distance", 'alignedDist',
"direction")[seq.int(ncol(align))]
return(align)
}
#' comapre w pcm
#' @description compare two pcm objects
#' @param pcm1,pcm2 object of pcm
#' @param method Alignment method. "Smith-Waterman" or "Needleman-Wunsch".
#' Default is "Smith-Waterma"
#' @param pseudo pseudocount
#' @param revcomp Check reverseComplement or not.
#' @return a list with names: motif1, motif2, alignmentScore,
#' startPos1, startPos2, endPos1, endPos2, alignmentLength.
compareProfiles <- function(pcm1, pcm2,
method=c("Smith-Waterman", "Needleman-Wunsch"),
pseudo=1,
revcomp=TRUE){
method <- match.arg(method,
choices = c("Smith-Waterman", "Needleman-Wunsch"))
hspF <- compare2profiles(pcm1, pcm2, method, pseudo)
if(!(pcm1@alphabet %in% c("DNA", "RNA")) || !revcomp){
hspF$direction <- "Forward"
return(hspF)
}
hspR <- compare2profiles(pcm1, matrixReverseComplement(pcm2),
method, pseudo)
if(hspF$score >= hspR$score){
hspF$direction <- "Forward"
return(hspF)
}else{
hspR$direction <- "Reverse"
return(hspR)
}
}
#' compare two profiles
#' @description compare two pcm object
#' @param pcm1,pcm2 object of pcm
#' @param method Alignment method. "Smith-Waterman" or "Needleman-Wunsch".
#' Default is "Smith-Waterma"
#' @param pseudo pseudocount
#' @return a list with names: motif1, motif2, alignmentScore,
#' startPos1, startPos2, endPos1, endPos2, alignmentLength.
compare2profiles <- function(pcm1, pcm2,
method = c("Smith-Waterman",
"Needleman-Wunsch"),
pseudo=1
){
method <- match.arg(method,
choices = c("Smith-Waterman", "Needleman-Wunsch"))
profile1 <- pcm1@mat
profile2 <- pcm2@mat
width1 <- ncol(profile1)
width2 <- ncol(profile2)
score <- getScore(pcm1, pcm2, pseudo)
if(method == "Needleman-Wunsch"){
dpScore <- dpGlobal(score, width1, width2)
hsp <- traceBackGlobal(dpScore, score, width1, width2)
}else{
dpScore <- dpLocal(score, width1, width2)
hsp <- traceBackLocal(dpScore, score, width1, width2)
}
dist <- getDistance(hsp, count1 = profile1, count2 = profile2,
P1 = pcm1@background, P2 = pcm2@background,
pseudo = pseudo)
hsp$distance <- dist[1]
hsp$alignedDist <- dist[2]
return(hsp)
}
#' Calculate pair_wise position score
#' @param pcm1,pcm2 object of pcm
#' @param pseudo pseudocount
#' @return A score matrix with nrow of ncol of pcm1
#' and ncol of ncol of pcm2.
getScore <- function(pcm1, pcm2, pseudo=1){
stopifnot("input is not pcm object"=is(pcm1, "pcm"))
stopifnot("input is not pcm object"=is(pcm2, "pcm"))
profile1 <- pcm1@mat
profile2 <- pcm2@mat
P1 <- pcm1@background
P2 <- pcm2@background
isAA <- pcm1@alphabet=="AA" && pcm2@alphabet=="AA"
score <- matrix(0,
nrow = ncol(profile1),
ncol = ncol(profile2))
for(i in seq.int(ncol(profile1))){
for(j in seq.int(ncol(profile2))){
if(isAA){##condense AA by chemical characteristics
score[i, j] <-
getALLRscoreFromCounts(condenseByGroup(profile1[, i]),
condenseByGroup(profile2[, j]),
condenseByGroup(P1),
condenseByGroup(P2), pseudo)
}else{
score[i, j] <-
getALLRscoreFromCounts(profile1[, i], profile2[, j],
P1, P2, pseudo)
}
}
}
return(score)
}
condenseByGroup <- function(x,
group=list(A=c("G", "A", "V", "L", "I"),
S=c("S", "C", "U", "T", "M"),
P=c("P"),
F=c("F", "Y", "W"),
H=c("H", "K", "R"),
D=c("D", "E", "N", "Q"))){
stopifnot(all(names(x) %in% unlist(group)))
stopifnot(is.list(group))
stopifnot(length(names(group))>0)
vapply(group, FUN = function(.ele){
sum(x[.ele], na.rm = TRUE)
}, FUN.VALUE = 0.0)
}
#' calculate I'
#' @param freq1 position frequence for matrix 1 position j
#' @param freq2 position frequence for matrix 2 position j
#' @param P background of profile1
#' @return numeric(1)
calI <- function(freq1, freq2, P){
sum(freq2*log(freq1/P)/log(2))
}
#' calculate frequence
#' @param count position counts
#' @param P background probility
#' @param pseudo pseudocount
#' @return numeric(1)
calF <- function(count,
P=rep(1/length(count), length(count)),
pseudo=1){
total <- sum(count)
f <- (count + P*pseudo)/(total+pseudo)
return(f)
}
#' calculate ALLR from counts
#' @param count1,count2 count in position j for matrix 1 or 2
#' @param P1,P2 background for matrix 1 or 2
#' @param pseudo pseudocount
#' @return numeric(1) of ALLR
getALLRscoreFromCounts <- function(count1, count2, P1, P2, pseudo){
freq1 <- calF(count1, P1, pseudo)
freq2 <- calF(count2, P2, pseudo)
I1 <- calI(freq1, freq2, P1)
I2 <- calI(freq2, freq1, P2)
total1 <- sum(count1)
total2 <- sum(count2)
score <- (I1*total2 + I2*total1)/(total1+total2)
return(score)
}
#' Dynamic programming function, local version
#' @param score ALLR scores, m x n matrix
#' @param m,n matrix width
#' @return score matrix
dpLocal <- function(score, m, n){
s <- 0
DP <- matrix(0, nrow = m, ncol = n)
DP[score[, 1]>0, 1] <- score[score[, 1]>0, 1]
DP[1, score[1, ]>0] <- score[1, score[1, ]>0]
for(i in seq.int(m)[-1]){
for(j in seq.int(n)[-1]){
s <- DP[i-1, j-1] + score[i, j]
DP[i, j] <- ifelse(s>0, s, 0)
}
}
return(DP)
}
#' Global alignment version
#' @param score ALLR scores, m x n matrix
#' @param m,n matrix width
#' @return score matrix
dpGlobal <- function(score, m, n){
s <- 0
DP <- matrix(0, nrow = m, ncol = n)
DP[, 1] <- score[, 1]
DP[1, ] <- score[1, ]
for(i in seq.int(m)[-1]){
for(j in seq.int(n)[-1]){
s <- DP[i-1, j-1] + score[i, j]
DP[i, j] <- s
}
}
return(DP)
}
#' traceback local
#' @param dpScore Dynamic programming score matrix
#' @param score ALLR scores, m x n matrix
#' @param m,n matrix width
#' @return a data.frame
traceBackLocal <- function(dpScore, score, m, n){
max <- max(dpScore)
maxpos <- which.max(dpScore)
maxpos <- maxpos[length(maxpos)]
j <- j_end <- ceiling(maxpos/m)
i <- i_end <- maxpos - m*(j_end - 1)
while(i>1 && j>1){
if(dpScore[i, j]>0){
i <- i-1
j <- j-1
}else{
i <- i+1
j <- j+1
break()
}
}
i_start <- i
j_start <- j
eval <- getEval(max, m, n)
pval <- Eval2Pval(eval)
return(data.frame(score=max,
width1=m,
width2=n,
i_start=i_start,
j_start=j_start,
i_end=i_end,
j_end=j_end,
length=i_end - i_start + 1,
P_value=pval))
}
#' traceback global
#' @param dpScore Dynamic programming score
#' @param score ALLR scores
#' @param m,n matrix width
#' @return a data.frame
traceBackGlobal <- function(dpScore, score, m, n){
max <- dpScore[m, n]
i_end <- m
j_end <- n
for(i in seq.int(m)){
if(dpScore[i, n]>=max){
max <- dpScore[i, n]
i_end <- i
j_end <- n
}
}
for(j in seq.int(n)){
if(dpScore[m, j]>=max){
max <- dpScore[m, j]
i_end <- m
j_end <- j
}
}
i <- i_end
j <- j_end
while(i>1 && j>1){
i <- i-1
j <- j-1
}
i_start <- i
j_start <- j
eval <- getEval(max, m, n)
pval <- Eval2Pval(eval)
return(data.frame(score=max,
width1=m,
width2=n,
i_start=i_start,
j_start=j_start,
i_end=i_end,
j_end=j_end,
length=i_end - i_start + 1,
P_value=pval))
}
#' Calculate distances between two profiles
#' @param hsp output of traceBack function
#' @param count1,count2 motif profile 1 or 2
#' @param P1,P2 background of profile 1 or 2
#' @param pseudo pseudocount
#' @return full distance and aligned distance.
getDistance <- function(hsp, count1, count2,
P1, P2, pseudo){
full1 <- sum(
apply(count1, 2, function(.ele)
getALLRscoreFromCounts(count1 = .ele, count2 = .ele,
P1=P1, P2=P1, pseudo = pseudo))
)
if(hsp$i_start<=hsp$i_end){
aligned1 <- sum(
apply(count1[, hsp$i_start:hsp$i_end, drop=FALSE], 2, function(.ele)
getALLRscoreFromCounts(count1 = .ele, count2 = .ele,
P1=P1, P2=P1, pseudo = pseudo))
)
}else{
aligned1 <- 0
}
full2 <- sum(
apply(count2, 2, function(.ele)
getALLRscoreFromCounts(count1 = .ele, count2 = .ele,
P1=P2, P2=P2, pseudo = pseudo))
)
if(hsp$i_start<=hsp$i_end){
aligned2 <- sum(
apply(count2[, hsp$j_start:hsp$j_end, drop=FALSE], 2, function(.ele)
getALLRscoreFromCounts(count1 = .ele, count2 = .ele,
P1=P2, P2=P2, pseudo = pseudo))
)
}else{
aligned2 <- 0
}
return(c(
dist1 = full1 + full2 - 2*hsp$score,
dist2 = aligned1 + aligned2 - 2*hsp$score
))
}
getEval <- function(alignmentScore, m, n){
Lambda <- 0.02094
K <- 0.26062
H <- 3.25810
K * m * n * exp (-Lambda*(alignmentScore*100))
}
Eval2Pval <- function(e){
1 - exp(-e)
}
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