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Properly access distance data

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This commit is contained in:
Elias Projahn 2021-10-21 14:26:03 +02:00
parent c0a1d965d7
commit 21a5817988
5 changed files with 12 additions and 18 deletions
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14
R/analyze.R
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@ -45,9 +45,8 @@ analyze <- function(preset, progress = NULL) {
# #
# A method describes a way to perform a computation on gene distance data # A method describes a way to perform a computation on gene distance data
# that results in a single score per gene. The function should accept the # that results in a single score per gene. The function should accept the
# distances data, the preset to apply (see [preset()]) and an optional # preset to apply (see [preset()]) and an optional progress function (that
# progress function (that may be called with a number between 0.0 and 1.0) # may be called with a number between 0.0 and 1.0) as its parameters.
# as its parameters.
# #
# The function should return a [data.table] with the following columns: # The function should return a [data.table] with the following columns:
# #
@ -62,19 +61,14 @@ analyze <- function(preset, progress = NULL) {
total_progress <- 0.0 total_progress <- 0.0
method_count <- length(preset$method_ids) method_count <- length(preset$method_ids)
results <- data.table(gene = genes$id) results <- data.table(gene = preset$gene_ids)
for (method_id in preset$method_ids) { for (method_id in preset$method_ids) {
method_progress <- if (!is.null(progress)) function(p) { method_progress <- if (!is.null(progress)) function(p) {
progress(total_progress + p / method_count) progress(total_progress + p / method_count)
} }
method_results <- methods[[method_id]]( method_results <- methods[[method_id]](preset, method_progress)
distances,
preset,
method_progress
)
setnames(method_results, "score", method_id) setnames(method_results, "score", method_id)
results <- merge( results <- merge(

4
R/clusteriness.R
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@ -36,11 +36,11 @@ clusteriness_priv <- function(data, height = 1000000) {
} }
# Process genes clustering their distance to telomeres. # Process genes clustering their distance to telomeres.
clusteriness <- function(distances, preset, progress = NULL) { clusteriness <- function(preset, progress = NULL) {
results <- data.table(gene = preset$gene_ids) results <- data.table(gene = preset$gene_ids)
# Prefilter the input data by species. # Prefilter the input data by species.
distances <- distances[species %chin% preset$species_ids] distances <- geposan::distances[species %chin% preset$species_ids]
# Add an index for quickly accessing data per gene. # Add an index for quickly accessing data per gene.
setkey(distances, gene) setkey(distances, gene)

4
R/correlation.R
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@ -1,12 +1,12 @@
# Compute the mean correlation coefficient comparing gene distances with a set # Compute the mean correlation coefficient comparing gene distances with a set
# of reference genes. # of reference genes.
correlation <- function(distances, preset, progress = NULL) { correlation <- function(preset, progress = NULL) {
species_ids <- preset$species_ids species_ids <- preset$species_ids
gene_ids <- preset$gene_ids gene_ids <- preset$gene_ids
reference_gene_ids <- preset$reference_gene_ids reference_gene_ids <- preset$reference_gene_ids
# Prefilter distances by species. # Prefilter distances by species.
distances <- distances[species %chin% species_ids] distances <- geposan::distances[species %chin% species_ids]
# Tranform data to get species as rows and genes as columns. We construct # Tranform data to get species as rows and genes as columns. We construct
# columns per species, because it requires fewer iterations, and transpose # columns per species, because it requires fewer iterations, and transpose

4
R/neural.R
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@ -1,7 +1,7 @@
# Find genes by training a neural network on reference position data. # Find genes by training a neural network on reference position data.
# #
# @param seed A seed to get reproducible results. # @param seed A seed to get reproducible results.
neural <- function(distances, preset, progress = NULL, seed = 448077) { neural <- function(preset, progress = NULL, seed = 448077) {
species_ids <- preset$species_ids species_ids <- preset$species_ids
reference_gene_ids <- preset$reference_gene_ids reference_gene_ids <- preset$reference_gene_ids
@ -9,7 +9,7 @@ neural <- function(distances, preset, progress = NULL, seed = 448077) {
gene_count <- length(preset$gene_ids) gene_count <- length(preset$gene_ids)
# Prefilter distances by species. # Prefilter distances by species.
distances <- distances[species %chin% species_ids] distances <- geposan::distances[species %chin% species_ids]
# Input data for the network. This contains the gene ID as an identifier # Input data for the network. This contains the gene ID as an identifier
# as well as the per-species gene distances as input variables. # as well as the per-species gene distances as input variables.

4
R/proximity.R
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@ -2,9 +2,9 @@
# #
# A score will be given to each gene such that 0.0 corresponds to the maximal # A score will be given to each gene such that 0.0 corresponds to the maximal
# mean distance across all genes and 1.0 corresponds to a distance of 0. # mean distance across all genes and 1.0 corresponds to a distance of 0.
proximity <- function(distances, preset, progress = NULL) { proximity <- function(preset, progress = NULL) {
# Prefilter distances by species and gene. # Prefilter distances by species and gene.
distances <- distances[ distances <- geposan::distances[
species %chin% preset$species_ids & gene %chin% preset$gene_ids species %chin% preset$species_ids & gene %chin% preset$gene_ids
] ]