HiCcompare2: Normalize and detect differences between Hi-C datasets when replicates of each experimental condition are available

Documented in cyclic_loess

#' Cyclic Loess normalization for Hi-C data
#' 
#' @param hicexp A hicexp object
#' @param iterations The number of iterations (cycles) 
#'     of loess normalization to perform. Defaults to 3.
#' @param span The span for loess normalization. Defaults to
#'     NA indicating that span will be automatically calculated
#'     using generalized cross validation.
#' @param parallel Logical. Should parallel processing be used?
#' @param verbose Logical. Should messages about loess normalization
#'     be printed to the screen.
#' 
#' @details This function performs cyclic loess normalization
#'    on a Hi-C experiment. multiHiCcompare's cyclic loess procedure
#'    is a modified version of Ballman's (2004) cyclic loess and
#'    the joint loess normalization used in the original HiCcompare.
#'    For each unique pair of samples in the hicexp object an MD plot
#'    is generated. A loess curve is fit to the MD plot and then the 
#'    fitted values are used to adjust the data. This is performed on
#'    all unique pairs and then repeated until convergence. 
#' @return A hicexp object that has been normalized. 
#' @export
#' @importFrom BiocParallel bplapply
#' @importFrom HiCcompare MD.plot1
#' @importFrom data.table rbindlist
#' @importFrom stats aggregate loess loess.control model.matrix 
#'     optimize p.adjust predict update D loess.smooth
#' @importFrom utils combn read.table tail write.table
#' @examples 
#' #' data("hicexp2")
#' hicexp2 <- cyclic_loess(hicexp2, span = 0.7)


cyclic_loess <- function(hicexp, iterations = 3, span = NA, 
                         parallel = FALSE, verbose = FALSE) {
  # check if data already normalized
  if (normalized(hicexp)) {
    stop("Data has already been normalized.")
  }
  # check span input
  if (!is.na(span)) {
    if (!is.numeric(span) || span <= 0 || span > 1) {
      stop("span must be set to NA or a value between 0 and 1")
    }
  }
  # check iterations input
  if (iterations != 3L) {
    warning("Typically it takes about 3 iterations for cyclic 
            loess to converge.")
  }
  # check for missing values
  if (any(is.na(hic_table(hicexp)))) {
    stop("hic_table contains missing values!")
  }
  # split up data by condition and perform cyclic loess
  normalized <- .loess_condition(hic_table(hicexp), 
                                 iterations = iterations, parallel = parallel, 
                                 verbose = verbose, span = span)
  # sort hic_table
  normalized <- normalized[order(chr, region1, region2),]
  # put back into hicexp object
  slot(hicexp, "hic_table") <- normalized
  slot(hicexp, "normalized") <- TRUE
  
  
  return(hicexp)
}




# background functions
### Perform cyclic loess for a condition
.loess_condition <- function(hic_table, iterations, parallel, verbose, span) {
  # split up data by chr
  table_list <- split(hic_table, hic_table$chr)
  # plug into parallelized loess function
  normalized <- smartApply(parallel, table_list, .cloess, 
                           iterations = iterations, verbose = verbose,
                           span = span)
  
  # recombine tables
  normalized <- data.table::rbindlist(normalized)
  return(normalized)
}

# perform cyclic loess on a table 
.cloess <- function(tab, iterations, verbose, span, degree = 1, 
                    loess.criterion = "gcv") {
  # make matrix of IFs
  IF_mat <- as.matrix(tab[, -c("chr", "region1", "region2", "D"), with = FALSE])
  # make index matrix
  idx_mat <- IF_mat
  idx_mat[idx_mat != 0] <- 1
  # log the matrix
  IF_mat <- log2(IF_mat + 1)
  n <- ncol(IF_mat)
  # begin cyclic loess
  for (i in seq(from = 1, to = iterations)) {
    for(j in seq(from = 1, to = (n-1))) {
      for (k in seq(from = (j+1), to = n)) {
        # # get rows with zeros
        # zeros1 <-  IF_mat[,k] == 0
        # zeros2 <- IF_mat[,j] == 0
        # zeros <- zeros1 | zeros2
        # M <- IF_mat[!zeros, k] - IF_mat[!zeros, j]
        # D <- tab$D[!zeros]
        M <- IF_mat[,k] - IF_mat[,j]
        D <- tab$D
        if (is.na(span)) {
          l <- .loess.as(x = D, y = M, degree = degree, 
                         criterion = loess.criterion,
                         control = loess.control(surface = "interpolate",
                                                 statistics = "approximate", 
                                                 trace.hat = "approximate"))
        } else {
          l <- .loess.as(x = D, y = M, degree = degree, user.span = span,
                         criterion = loess.criterion,
                         control = loess.control(surface = "interpolate",
                                                 statistics = "approximate", 
                                                 trace.hat = "approximate"))
        }
        # calculate gcv and AIC
        traceL <- l$trace.hat
        sigma2 <- sum(l$residuals^2)/(l$n - 1)
        aicc <- log(sigma2) + 1 + 2 * (2 * (traceL + 1))/(l$n - traceL -2)
        gcv <- l$n * sigma2/(l$n - traceL)^2
        # print the span picked by gcv
        if (verbose) {
          message("Span for loess: ", l$pars$span)
          message("GCV for loess: ", gcv)
          message("AIC for loess: ", aicc)
        }
        # adjust IFs
        # IF_mat[!zeros,j] <- IF_mat[!zeros,j] + l$fitted/2
        # IF_mat[!zeros,k] <- IF_mat[!zeros,k] - l$fitted/2
        IF_mat[,j] <- IF_mat[,j] + l$fitted/2
        IF_mat[,k] <- IF_mat[,k] - l$fitted/2
      }
    }
  }
  # anti-log IFs
  IF_mat <- (2^IF_mat) - 1
  # reset zeros
  IF_mat <- IF_mat * idx_mat
  # set negative values to 0
  IF_mat[IF_mat < 0] <- 0
  # fix any potential Infs or NaN's
  IF_mat[is.nan(IF_mat)] <- 0
  IF_mat[is.infinite(IF_mat)] <- 0
  # recombine table
  tab <- cbind(tab[, 1:4, with = FALSE], IF_mat)
  return(tab)
}



# loess with Automatic Smoothing Parameter Selection adjusted possible
# range of smoothing originally from fANCOVA package
.loess.as <- function(x, y, degree = 1, criterion = c("aicc", "gcv"),
                      family = c("gaussian",
                                 "symmetric"), user.span = NULL, plot = FALSE, ...) {
  criterion <- match.arg(criterion)
  family <- match.arg(family)
  x <- as.matrix(x)

  data.bind <- data.frame(x = x, y = y)
  if (ncol(x) == 1) {
    names(data.bind) <- c("x", "y")
  } else {
    names(data.bind) <- c("x1", "x2", "y")
  }
  
  opt.span <- function(model, criterion = c("aicc", "gcv"),
                       span.range = c(0.01, 0.9)) {
    as.crit <- function(x) {
      span <- x$pars$span
      traceL <- x$trace.hat
      sigma2 <- sum(x$residuals^2)/(x$n - 1)
      aicc <- log(sigma2) + 1 + 2 * (2 * (traceL + 1))/(x$n - traceL -
                                                          2)
      gcv <- x$n * sigma2/(x$n - traceL)^2
      result <- list(span = span, aicc = aicc, gcv = gcv)
      return(result)
    }
    criterion <- match.arg(criterion)
    fn <- function(span) {
      mod <- stats::update(model, span = span)
      as.crit(mod)[[criterion]]
    }
    result <- optimize(fn, span.range)
    return(list(span = result$minimum, criterion = result$objective))
  }
  
  if (ncol(x) == 1) {
    if (is.null(user.span)) {
      fit0 <- loess(y ~ x, degree = degree, family = family, data = data.bind,
                    ...)
      span1 <- opt.span(fit0, criterion = criterion)$span
    } else {
      span1 <- user.span
    }
    fit <- loess(y ~ x, degree = degree, span = span1, family = family,
                 data = data.bind, ...)
  } else {
    if (is.null(user.span)) {
      fit0 <- loess(y ~ x1 + x2, degree = degree, family = family,
                    data.bind, ...)
      span1 <- opt.span(fit0, criterion = criterion)$span
    } else {
      span1 <- user.span
    }
    fit <- loess(y ~ x1 + x2, degree = degree, span = span1, family = family,
                 data = data.bind, ...)
  }
  if (plot) {
    if (ncol(x) == 1) {
      m <- 100
      x.new <- seq(min(x), max(x), length.out = m)
      fit.new <- predict(fit, data.frame(x = x.new))
      plot(x, y, col = "lightgrey", xlab = "x", ylab = "m(x)", ...)
      lines(x.new, fit.new, lwd = 1.5, ...)
    } else {
      m <- 50
      x1 <- seq(min(data.bind$x1), max(data.bind$x1), len = m)
      x2 <- seq(min(data.bind$x2), max(data.bind$x2), len = m)
      x.new <- expand.grid(x1 = x1, x2 = x2)
      fit.new <- matrix(predict(fit, x.new), m, m)
      persp(x1, x2, fit.new, theta = 40, phi = 30, ticktype = "detailed",
            xlab = "x1", ylab = "x2", zlab = "y", col = "lightblue",
            expand = 0.6)
    }
  }
  return(fit)
}

jstansfield0/HiCcompare2 documentation built on May 4, 2021, 8:36 a.m.

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jstansfield0/HiCcompare2
Normalize and detect differences between Hi-C datasets when replicates of each experimental condition are available

R/cyclic_loess.R
In jstansfield0/HiCcompare2: Normalize and detect differences between Hi-C datasets when replicates of each experimental condition are available

Defines functions .loess.as .cloess .loess_condition cyclic_loess

Documented in cyclic_loess

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jstansfield0/HiCcompare2 Normalize and detect differences between Hi-C datasets when replicates of each experimental condition are available

R/cyclic_loess.R In jstansfield0/HiCcompare2: Normalize and detect differences between Hi-C datasets when replicates of each experimental condition are available

Defines functions .loess.as .cloess .loess_condition cyclic_loess

Documented in cyclic_loess

R Package Documentation

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We want your feedback!

jstansfield0/HiCcompare2
Normalize and detect differences between Hi-C datasets when replicates of each experimental condition are available

R/cyclic_loess.R
In jstansfield0/HiCcompare2: Normalize and detect differences between Hi-C datasets when replicates of each experimental condition are available