Revisiting prior families for trees: Part VIII
Jason Willwerscheid
7/22/2020
Last updated: 2020-08-09
Checks: 6 0
Knit directory: drift-workflow/analysis/
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suppressMessages({
library(flashier)
library(drift.alpha)
library(tidyverse)
})I use the method from the previous analysis but I add an outgroup to a four-population tree to see what happens. Hmm…
set.seed(666)
p <- 10000
resid_sd <- 0.1
# Define tree by mean branch length at each depth:
branch_means <- rep(1, 3)
branch_sds <- rep(0, 3)
depth <- length(branch_means)
npop_pure <- 2^(depth - 1)
# Define admixtures by admixture proportions:
admix_pops <- matrix(nrow = 0, ncol = 0)
outgroup <- TRUE
npop_admix <- ncol(admix_pops)
npop <- npop_pure + npop_admix + outgroup
n <- sample(30:100, npop, replace = TRUE)
# n <- rep(50, npop)
K <- 2^depth - 1
FF <- matrix(nrow = p, ncol = K)
k <- 1
for (d in 1:depth) {
for (i in 1:(2^(d - 1))) {
FF[, k] <- rnorm(p, sd = branch_means[d] + rnorm(1, sd = branch_sds[d]))
k <- k + 1
}
}
tree_mat <- matrix(0, nrow = npop_pure, ncol = K)
k <- 1
for (d in 1:depth) {
size <- 2^(depth - d)
for (i in 1:(2^(d - 1))) {
tree_mat[((i - 1) * size + 1):(i * size), k] <- 1
k <- k + 1
}
}
pop_means <- FF %*% t(tree_mat)
if (npop_admix > 0) {
pop_means <- cbind(pop_means, pop_means %*% admix_pops)
}
if (outgroup) {
pop_means <- cbind(pop_means, rnorm(p, mean = 0, sd = sqrt(sum(branch_sds^2))))
}
Y <- NULL
for (i in 1:npop) {
Y <- rbind(Y, matrix(pop_means[, i], nrow = n[i], ncol = p, byrow = TRUE))
}
Y <- Y + rnorm(sum(n) * p, sd = resid_sd)
plot_dr <- function(dr) {
sd <- sqrt(dr$prior_s2)
L <- dr$EL
LDsqrt <- L %*% diag(sd)
K <- ncol(LDsqrt)
plot_loadings(LDsqrt[,1:K], rep(letters[1:npop], n)) +
scale_color_brewer(palette="Set3")
}
threepm.fn = function(x, s, g_init, fix_g, output, ...) {
if (is.null(g_init)) {
nllik_given_ab <- function(par) {
g_init <- ashr::unimix(rep(1/3, 3), a = c(-par[1], 0, par[2]), b = c(-par[1], 0, par[2]))
ebnm_res <- ebnm::ebnm_ash(x, s, g_init = g_init)
return(-ebnm_res$log_likelihood)
}
opt_res <- optim(
par = c(1, 1),
fn = nllik_given_ab,
method = "L-BFGS-B",
lower = c(0, 0),
upper = c(Inf, Inf)
)
par <- opt_res$par
g_init <- ashr::unimix(rep(1/3, 3), a = c(-par[1], 0, par[2]), b = c(-par[1], 0, par[2]))
}
return(flashier:::ebnm.nowarn(x = x,
s = s,
g_init = g_init,
fix_g = fix_g,
output = output,
prior_family = "ash",
prior = c(1, 1, 1),
...))
}
prior.threepm = function(...) {
return(as.prior(sign = 0, ebnm.fn = function(x, s, g_init, fix_g, output) {
threepm.fn(x, s, g_init, fix_g, output, ...)
}))
}
flexpm.fn = function(x, s, g_init, fix_g, output, ...) {
if (is.null(g_init)) {
nllik_given_ab <- function(par) {
g_init <- ashr::unimix(rep(1/4, 4), a = c(-par[1], 0, par[2], -par[1]), b = c(-par[1], 0, par[2], par[2]))
ebnm_res <- ebnm::ebnm_ash(x, s, g_init = g_init)
return(-ebnm_res$log_likelihood)
}
opt_res <- optim(
par = c(1, 1),
fn = nllik_given_ab,
method = "L-BFGS-B",
lower = c(0, 0),
upper = c(Inf, Inf)
)
par <- opt_res$par
g_init <- ashr::unimix(rep(1/4, 4), a = c(-par[1], 0, par[2], -par[1]), b = c(-par[1], 0, par[2], par[2]))
}
return(flashier:::ebnm.nowarn(x = x,
s = s,
g_init = g_init,
fix_g = fix_g,
output = output,
prior_family = "ash",
prior = c(1, 1, 1, 1),
...))
}
prior.flexpm = function(...) {
return(as.prior(sign = 0, ebnm.fn = function(x, s, g_init, fix_g, output) {
threepm.fn(x, s, g_init, fix_g, output, ...)
}))
}
init.mean.factor <- function(resids, zero.idx) {
u <- matrix(1, nrow = nrow(resids), ncol = 1)
u[zero.idx, 1] <- 0
v <- t(solve(crossprod(u), crossprod(u, resids)))
return(list(u, v))
}
init.split.factor <- function(resids, zero.idx) {
svd.res <- svd(resids, nu = 1, nv = 1)
u <- svd.res$u
u[zero.idx] <- 0
u <- matrix(sign(u), ncol = 1)
v <- t(solve(crossprod(u), crossprod(u, resids)))
return(list(u, v))
}Before relaxation:
fl <- flash.init(Y) %>%
flash.set.verbose(0) %>%
flash.init.factors(EF = init.mean.factor(Y, NULL),
prior.family = c(prior.threepm(), prior.normal())) %>%
flash.fix.loadings(kset = 1, mode = 1L) %>%
flash.backfit() %>%
flash.add.greedy(Kmax = 1, prior.family = c(prior.threepm(), prior.normal()))
add_split <- function(fl, eigen.thresh = 0.5) {
svd.res <- svd(Y - fitted(fl), nu = 10, nv = 10)
n.eigen <- sum(svd.res$d > eigen.thresh * svd.res$d[1])
if (n.eigen > 1) {
varimax.res <- varimax(svd.res$u[, 1:n.eigen], normalize = FALSE)
EL <- varimax.res$loadings[, 1, drop = FALSE]
EF <- (svd.res$v[, 1:n.eigen] %*% t(solve(varimax.res$rotmat)))[, 1, drop = FALSE]
} else {
EL <- svd.res$u[, 1, drop = FALSE]
EF <- svd.res$v[, 1, drop = FALSE]
}
fl.new <- fl %>%
flash.init.factors(EF = list(EL, EF),
prior.family = c(prior.threepm(), prior.normal())) %>%
flash.backfit(kset = fl$n.factors + 1)
return(fl.new)
}
fl2 <- fl
for (i in 1:2) {
fl2 <- add_split(fl)
}
plot_dr(init_from_flash(fl2))
After relaxation:
fl.relax <- fl2
for (k in 2:fl.relax$n.factors) {
fl.relax$flash.fit$g[[k]][[1]]$pi <- rep(0.25, 4)
fl.relax$flash.fit$g[[k]][[1]]$a <- c(fl.relax$flash.fit$g[[k]][[1]]$a,
0.9 * min(fl.relax$flash.fit$g[[k]][[1]]$a))
fl.relax$flash.fit$g[[k]][[1]]$b <- c(fl.relax$flash.fit$g[[k]][[1]]$b,
0.9 * max(fl.relax$flash.fit$g[[k]][[1]]$b))
fl.relax$flash.fit$ebnm.fn[[k]][[1]] <- prior.unimodal()[[1]]$ebnm.fn
}
fl.relax <- fl.relax %>%
flash.backfit()
plot_dr(init_from_flash(fl.relax))
sessionInfo()#> R version 3.5.3 (2019-03-11)
#> Platform: x86_64-apple-darwin15.6.0 (64-bit)
#> Running under: macOS Mojave 10.14.6
#>
#> Matrix products: default
#> BLAS: /Library/Frameworks/R.framework/Versions/3.5/Resources/lib/libRblas.0.dylib
#> LAPACK: /Library/Frameworks/R.framework/Versions/3.5/Resources/lib/libRlapack.dylib
#>
#> locale:
#> [1] en_US.UTF-8/en_US.UTF-8/en_US.UTF-8/C/en_US.UTF-8/en_US.UTF-8
#>
#> attached base packages:
#> [1] stats graphics grDevices utils datasets methods base
#>
#> other attached packages:
#> [1] forcats_0.4.0 stringr_1.4.0 dplyr_0.8.0.1
#> [4] purrr_0.3.2 readr_1.3.1 tidyr_0.8.3
#> [7] tibble_2.1.1 ggplot2_3.2.0 tidyverse_1.2.1
#> [10] drift.alpha_0.0.10 flashier_0.2.7
#>
#> loaded via a namespace (and not attached):
#> [1] Rcpp_1.0.4.6 lubridate_1.7.4 invgamma_1.1
#> [4] lattice_0.20-38 assertthat_0.2.1 rprojroot_1.3-2
#> [7] digest_0.6.18 truncnorm_1.0-8 R6_2.4.0
#> [10] cellranger_1.1.0 plyr_1.8.4 backports_1.1.3
#> [13] evaluate_0.13 httr_1.4.0 pillar_1.3.1
#> [16] rlang_0.4.2 lazyeval_0.2.2 readxl_1.3.1
#> [19] rstudioapi_0.10 ebnm_0.1-21 irlba_2.3.3
#> [22] whisker_0.3-2 Matrix_1.2-15 rmarkdown_1.12
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#> [31] xfun_0.6 pkgconfig_2.0.2 SQUAREM_2017.10-1
#> [34] htmltools_0.3.6 tidyselect_0.2.5 workflowr_1.2.0
#> [37] withr_2.1.2 crayon_1.3.4 grid_3.5.3
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