FinalSimulationCode/simsCATE_gam_highdim.R
In Larsvanderlaan/npcausalML: Nonparametric estimation of the relative risk function
library(SuperLearner)
library(npcausalML)
library(future)
source("./FinalSimulationCode/simCATEHighDim.R")
#plan( cluster = 10, workers = 3, globals = TRUE)
nsims<- 1000
SL.gam1 <- function(Y, X, newX, family, obsWeights, cts.num = 4,...) {
deg.gam <- 1
SuperLearner::SL.gam(Y, X, newX, family, obsWeights, deg.gam, cts.num,... )
}
SL.gam2 <- function(Y, X, newX, family, obsWeights, cts.num = 4,...) {
deg.gam <- 2
SuperLearner::SL.gam(Y, X, newX, family, obsWeights, deg.gam, cts.num,... )
}
SL.gam3 <- function(Y, X, newX, family, obsWeights, cts.num = 4,...) {
deg.gam <- 3
SuperLearner::SL.gam(Y, X, newX, family, obsWeights, deg.gam, cts.num,... )
}
SL.gam4 <- function(Y, X, newX, family, obsWeights, cts.num = 4,...) {
deg.gam <- 4
SuperLearner::SL.gam(Y, X, newX, family, obsWeights, deg.gam, cts.num,... )
}
SL.gam5 <- function(Y, X, newX, family, obsWeights, cts.num = 4,...) {
deg.gam <- 5
SuperLearner::SL.gam(Y, X, newX, family, obsWeights, deg.gam, cts.num,... )
}
list_of_sieves_high_dim <- list(
NULL,
fourier_basis$new(orders = c(1,0)),
fourier_basis$new(orders = c(2,0)),
fourier_basis$new(orders = c(3,0))
)
lrnr_gam1 <- Lrnr_pkg_SuperLearner$new("SL.gam1" , name = "Lrnr_gam_s1_x")
lrnr_gam2 <- Lrnr_pkg_SuperLearner$new("SL.gam2", name = "Lrnr_gam_s2_x")
lrnr_gam3 <- Lrnr_pkg_SuperLearner$new("SL.gam3", name = "Lrnr_gam_s3_x")
lrnr_gam4 <- Lrnr_pkg_SuperLearner$new("SL.gam4" , name = "Lrnr_gam_s4_x")
lrnr_gam5 <- Lrnr_pkg_SuperLearner$new("SL.gam5" , name = "Lrnr_gam_s5_x")
onesim <- function(n) {
print(n)
print(pos)
print(hard)
sieve_list <- list_of_sieves_high_dim
data <- as.data.frame(sim.CATEHighDim(n, hard, pos))
W <- data[,grep("^W", colnames(data))]
A <- data$A
Y <- data$Y
EY1Wtrue <- data$EY1W
EY0Wtrue <- data$EY0W
pA1Wtrue <- data$pA1W
EYWtrue <- ifelse(A==1, EY1Wtrue, EY0Wtrue)
CATE <- EY1Wtrue - EY0Wtrue
# sieve method
lrnr_Y <- make_learner(Pipeline, Lrnr_cv$new(
Lrnr_stratified$new(Stack$new(
Lrnr_xgboost$new(max_depth =3),
Lrnr_xgboost$new(max_depth =4),
Lrnr_xgboost$new(max_depth =5),
lrnr_gam2, lrnr_gam5), "A"))
, Lrnr_cv_selector$new(loss_squared_error))
lrnr_A <- make_learner(Pipeline, Lrnr_cv$new(
Stack$new(
Lrnr_xgboost$new(max_depth =3),
Lrnr_xgboost$new(max_depth =4),
Lrnr_xgboost$new(max_depth =5),
lrnr_gam2, lrnr_gam5)
)
, Lrnr_cv_selector$new(loss_squared_error))
data_train <- data #as.data.frame(sim.CATE(n, hard, pos))
initial_likelihood <- npcausalML:::estimate_initial_likelihood(W=data_train[,grep("W", colnames(data_train))], data_train$A, data_train$Y, weights = rep(1,n), lrnr_A, lrnr_Y, folds = 2)
data1 <- data
data0 <- data
data1$A <- 1
data0$A <- 0
folds <- initial_likelihood$internal$folds
taskY <- sl3_Task$new(data, covariates = c(grep("W", colnames(data_train), value = T), "A"), outcome = "Y", folds = folds)
taskY0 <- sl3_Task$new(data0, covariates = c(grep("W", colnames(data_train), value = T), "A"), outcome = "Y", folds = folds)
taskY1 <- sl3_Task$new(data1, covariates = c(grep("W", colnames(data_train), value = T), "A"), outcome = "Y", folds = folds)
taskA <- sl3_Task$new(data, covariates = c(grep("W", colnames(data_train), value = T)), outcome = "A", folds = folds)
pA1W_est <- initial_likelihood$internal$sl3_Learner_pA1W_trained$predict(taskA)
EY1W_est <- initial_likelihood$internal$sl3_Learner_EYAW_trained$predict(taskY1)
EY0W_est <- initial_likelihood$internal$sl3_Learner_EYAW_trained$predict(taskY0)
pA1W_est <- pmax(pA1W_est, 0.01)
pA1W_est <- pmin(pA1W_est, 0.99)
lrnr_gam <- list( lrnr_gam1, lrnr_gam2, lrnr_gam3, lrnr_gam4, lrnr_gam5 )
lrnr_gam_sl <- Lrnr_sl$new(lrnr_gam, metalearner = Lrnr_cv_selector$new(loss_squared_error))
lrnr_lm <- list(Lrnr_earth$new(), Lrnr_glm$new())
CATE_library <- c(lrnr_gam, lrnr_lm )
CATE_library_subst <- c(CATE_library ,list(lrnr_gam_sl ))
subst_compare <- Stack$new(CATE_library_subst)
print("start")
subst_EY1W_trained <-subst_compare$train(taskY1[A==1]$next_in_chain(covariates = grep("W[0-9]+", colnames(data), value = T)))
subst_EY0W_trained <- subst_compare$train(taskY0[A==0]$next_in_chain(covariates = grep("W[0-9]+", colnames(data), value = T)))
print("END")
subst_EY1W <-subst_EY1W_trained$predict(taskY1$next_in_chain(covariates = grep("W[0-9]+", colnames(data), value = T)))
subst_EY0W <- subst_EY0W_trained$predict(taskY0$next_in_chain(covariates = grep("W[0-9]+", colnames(data), value = T)))
subst_CATE <- subst_EY1W - subst_EY0W #subst_compare_trained$predict(taskY1) - subst_compare_trained$predict(taskY0)
# apply(subst_EY1W -subst_EY0W , 2, function(p) {mean((p - CATE)^2)})
# apply(subst_compare_trained$predict(taskY1) - subst_compare_trained$predict(taskY0), 2, function(p) {mean((p - CATE)^2)})
print("Jrtr")
fit_npcausalML <- EP_learn(CATE_library,V = as.data.frame(W), A = A, Y = Y, EY1W = EY1W_est , EY0W = EY0W_est , pA1W = pA1W_est, sieve_basis_generator_list = list_of_sieves_high_dim ,EP_learner_spec = EP_learner_spec_CATE, cross_validate = TRUE, nfolds = 2)
preds <- fit_npcausalML$full_predictions
# Compute least-squares risk of predictions using oracle loss function.
risks_oracle <- as.vector(apply(preds, 2, function(theta) {
mean((theta - CATE)^2)
}) )
print(risks_oracle)
# Compute estimated cross-validated one-step risk of predictions
cvrisksDR <- as.vector(apply(fit_npcausalML$cv_predictions, 2, function(theta) {
loss <- efficient_loss_function_CATE(W, theta, A, Y, EY1W_est,EY0W_est, pA1W_est )
mean(loss)
}))#[-grep("IPW", colnames(fit_npcausalML$cv_predictions))])
# Compute estimated cross-validated oracle one-step risk of predictions
cvrisksDRoracle <- as.vector(apply(fit_npcausalML$cv_predictions, 2, function(theta) {
loss <- efficient_loss_function_CATE(W, theta, A, Y, EY1Wtrue,EY0Wtrue, pA1Wtrue )
mean(loss)
}))#[-grep("IPW", colnames(fit_npcausalML$cv_predictions))])
lrnrs_full <- colnames(fit_npcausalML$cv_predictions)
lrnrs <- gsub("[._]sieve_fourier.+", "", lrnrs_full)
lrnrs <- gsub("_no_sieve", "", lrnrs)
degree <- as.numeric(stringr::str_match(lrnrs_full, "fourier_basis_([0-9]+)")[,2])
degree[grep("no_sieve", lrnrs_full)] <- 0
tmp <- data.table(lrnrs_full, lrnrs , degree, risk = cvrisksDR, risks_oracle = risks_oracle, cvrisksDR = cvrisksDR, cvrisksDRoracle)
gam_keep <- tmp[grep("gam", lrnrs_full),risks_oracle[which.min(risk)], by = degree]$V1
names(gam_keep) <- paste0("Lrnr_gam_cv", "_fourier.basis_", 0:3, "_plugin")
risks_oracle <- c(risks_oracle, gam_keep)
gam_keep <- tmp[grep("gam", lrnrs_full),cvrisksDR[which.min(risk)], by = degree]$V1
names(gam_keep) <- paste0("Lrnr_gam_cv", "_fourier.basis_", 0:3, "_plugin")
cvrisksDR <- c(cvrisksDR, gam_keep)
gam_keep <- tmp[grep("gam", lrnrs_full),cvrisksDRoracle[which.min(risk)], by = degree]$V1
names(gam_keep) <- paste0("Lrnr_gam_cv", "_fourier.basis_", 0:3, "_plugin")
cvrisksDRoracle <- c(cvrisksDRoracle, gam_keep)
sieve_names <- c(colnames(fit_npcausalML$cv_predictions), names(gam_keep))
CATE_library <- c(CATE_library, list(lrnr_gam_sl))
CATEonestepbench <- DR_learner(CATE_library, as.data.frame(W), A, Y, EY1W_est, EY0W_est, pA1W_est, NULL, NULL)
CATEonestepbench <- apply(CATEonestepbench, 2, function(pred) {
mean((pred - CATE)^2)
})
names(CATEonestepbench) <- c(unique(tmp$lrnrs) , "Lrnr_gam_cv")
CATEonestepbenchoracle <- DR_learner(CATE_library, W, A, Y, EY1Wtrue, EY0Wtrue, pA1Wtrue, NULL, NULL)
CATEonestepbenchoracle <- apply(CATEonestepbenchoracle, 2, function(pred) {
mean((pred - CATE)^2)
})
names(CATEonestepbenchoracle) <- c(unique(tmp$lrnrs), "Lrnr_gam_cv")
risk_subst<- apply(subst_CATE, 2, function(pred) {
mean((pred - CATE)^2)
})
risk_subst_cv <- mean((EY1W_est - EY0W_est - CATE)^2)
list(risk_subst_cv = risk_subst_cv, risk_subst = risk_subst, CATEonestepbenchoracle =CATEonestepbenchoracle, CATEonestepbench = CATEonestepbench, sieve =data.frame(sieve_names, cvrisksDRoracle, cvrisksDR, risks_oracle))
}
hard <- hard == "TRUE"
pos <- pos == "TRUE"
n <- as.numeric(n)
simresults <- lapply(1:nsims, function(i){try({
print(i)
onesim(n)
})
})
save(simresults, file = paste0("mainSimResults2/","simsCATE", hard,pos, "n", n, "_gam_highDim"))
Larsvanderlaan/npcausalML documentation built on July 30, 2023, 4:32 p.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
library(SuperLearner)
library(npcausalML)
library(future)
source("./FinalSimulationCode/simCATEHighDim.R")
#plan( cluster = 10, workers = 3, globals = TRUE)
nsims<- 1000
SL.gam1 <- function(Y, X, newX, family, obsWeights, cts.num = 4,...) {
deg.gam <- 1
SuperLearner::SL.gam(Y, X, newX, family, obsWeights, deg.gam, cts.num,... )
}
SL.gam2 <- function(Y, X, newX, family, obsWeights, cts.num = 4,...) {
deg.gam <- 2
SuperLearner::SL.gam(Y, X, newX, family, obsWeights, deg.gam, cts.num,... )
}
SL.gam3 <- function(Y, X, newX, family, obsWeights, cts.num = 4,...) {
deg.gam <- 3
SuperLearner::SL.gam(Y, X, newX, family, obsWeights, deg.gam, cts.num,... )
}
SL.gam4 <- function(Y, X, newX, family, obsWeights, cts.num = 4,...) {
deg.gam <- 4
SuperLearner::SL.gam(Y, X, newX, family, obsWeights, deg.gam, cts.num,... )
}
SL.gam5 <- function(Y, X, newX, family, obsWeights, cts.num = 4,...) {
deg.gam <- 5
SuperLearner::SL.gam(Y, X, newX, family, obsWeights, deg.gam, cts.num,... )
}
list_of_sieves_high_dim <- list(
NULL,
fourier_basis$new(orders = c(1,0)),
fourier_basis$new(orders = c(2,0)),
fourier_basis$new(orders = c(3,0))
)
lrnr_gam1 <- Lrnr_pkg_SuperLearner$new("SL.gam1" , name = "Lrnr_gam_s1_x")
lrnr_gam2 <- Lrnr_pkg_SuperLearner$new("SL.gam2", name = "Lrnr_gam_s2_x")
lrnr_gam3 <- Lrnr_pkg_SuperLearner$new("SL.gam3", name = "Lrnr_gam_s3_x")
lrnr_gam4 <- Lrnr_pkg_SuperLearner$new("SL.gam4" , name = "Lrnr_gam_s4_x")
lrnr_gam5 <- Lrnr_pkg_SuperLearner$new("SL.gam5" , name = "Lrnr_gam_s5_x")
onesim <- function(n) {
print(n)
print(pos)
print(hard)
sieve_list <- list_of_sieves_high_dim
data <- as.data.frame(sim.CATEHighDim(n, hard, pos))
W <- data[,grep("^W", colnames(data))]
A <- data$A
Y <- data$Y
EY1Wtrue <- data$EY1W
EY0Wtrue <- data$EY0W
pA1Wtrue <- data$pA1W
EYWtrue <- ifelse(A==1, EY1Wtrue, EY0Wtrue)
CATE <- EY1Wtrue - EY0Wtrue
# sieve method
lrnr_Y <- make_learner(Pipeline, Lrnr_cv$new(
Lrnr_stratified$new(Stack$new(
Lrnr_xgboost$new(max_depth =3),
Lrnr_xgboost$new(max_depth =4),
Lrnr_xgboost$new(max_depth =5),
lrnr_gam2, lrnr_gam5), "A"))
, Lrnr_cv_selector$new(loss_squared_error))
lrnr_A <- make_learner(Pipeline, Lrnr_cv$new(
Stack$new(
Lrnr_xgboost$new(max_depth =3),
Lrnr_xgboost$new(max_depth =4),
Lrnr_xgboost$new(max_depth =5),
lrnr_gam2, lrnr_gam5)
)
, Lrnr_cv_selector$new(loss_squared_error))
data_train <- data #as.data.frame(sim.CATE(n, hard, pos))
initial_likelihood <- npcausalML:::estimate_initial_likelihood(W=data_train[,grep("W", colnames(data_train))], data_train$A, data_train$Y, weights = rep(1,n), lrnr_A, lrnr_Y, folds = 2)
data1 <- data
data0 <- data
data1$A <- 1
data0$A <- 0
folds <- initial_likelihood$internal$folds
taskY <- sl3_Task$new(data, covariates = c(grep("W", colnames(data_train), value = T), "A"), outcome = "Y", folds = folds)
taskY0 <- sl3_Task$new(data0, covariates = c(grep("W", colnames(data_train), value = T), "A"), outcome = "Y", folds = folds)
taskY1 <- sl3_Task$new(data1, covariates = c(grep("W", colnames(data_train), value = T), "A"), outcome = "Y", folds = folds)
taskA <- sl3_Task$new(data, covariates = c(grep("W", colnames(data_train), value = T)), outcome = "A", folds = folds)
pA1W_est <- initial_likelihood$internal$sl3_Learner_pA1W_trained$predict(taskA)
EY1W_est <- initial_likelihood$internal$sl3_Learner_EYAW_trained$predict(taskY1)
EY0W_est <- initial_likelihood$internal$sl3_Learner_EYAW_trained$predict(taskY0)
pA1W_est <- pmax(pA1W_est, 0.01)
pA1W_est <- pmin(pA1W_est, 0.99)
lrnr_gam <- list( lrnr_gam1, lrnr_gam2, lrnr_gam3, lrnr_gam4, lrnr_gam5 )
lrnr_gam_sl <- Lrnr_sl$new(lrnr_gam, metalearner = Lrnr_cv_selector$new(loss_squared_error))
lrnr_lm <- list(Lrnr_earth$new(), Lrnr_glm$new())
CATE_library <- c(lrnr_gam, lrnr_lm )
CATE_library_subst <- c(CATE_library ,list(lrnr_gam_sl ))
subst_compare <- Stack$new(CATE_library_subst)
print("start")
subst_EY1W_trained <-subst_compare$train(taskY1[A==1]$next_in_chain(covariates = grep("W[0-9]+", colnames(data), value = T)))
subst_EY0W_trained <- subst_compare$train(taskY0[A==0]$next_in_chain(covariates = grep("W[0-9]+", colnames(data), value = T)))
print("END")
subst_EY1W <-subst_EY1W_trained$predict(taskY1$next_in_chain(covariates = grep("W[0-9]+", colnames(data), value = T)))
subst_EY0W <- subst_EY0W_trained$predict(taskY0$next_in_chain(covariates = grep("W[0-9]+", colnames(data), value = T)))
subst_CATE <- subst_EY1W - subst_EY0W #subst_compare_trained$predict(taskY1) - subst_compare_trained$predict(taskY0)
# apply(subst_EY1W -subst_EY0W , 2, function(p) {mean((p - CATE)^2)})
# apply(subst_compare_trained$predict(taskY1) - subst_compare_trained$predict(taskY0), 2, function(p) {mean((p - CATE)^2)})
print("Jrtr")
fit_npcausalML <- EP_learn(CATE_library,V = as.data.frame(W), A = A, Y = Y, EY1W = EY1W_est , EY0W = EY0W_est , pA1W = pA1W_est, sieve_basis_generator_list = list_of_sieves_high_dim ,EP_learner_spec = EP_learner_spec_CATE, cross_validate = TRUE, nfolds = 2)
preds <- fit_npcausalML$full_predictions
# Compute least-squares risk of predictions using oracle loss function.
risks_oracle <- as.vector(apply(preds, 2, function(theta) {
mean((theta - CATE)^2)
}) )
print(risks_oracle)
# Compute estimated cross-validated one-step risk of predictions
cvrisksDR <- as.vector(apply(fit_npcausalML$cv_predictions, 2, function(theta) {
loss <- efficient_loss_function_CATE(W, theta, A, Y, EY1W_est,EY0W_est, pA1W_est )
mean(loss)
}))#[-grep("IPW", colnames(fit_npcausalML$cv_predictions))])
# Compute estimated cross-validated oracle one-step risk of predictions
cvrisksDRoracle <- as.vector(apply(fit_npcausalML$cv_predictions, 2, function(theta) {
loss <- efficient_loss_function_CATE(W, theta, A, Y, EY1Wtrue,EY0Wtrue, pA1Wtrue )
mean(loss)
}))#[-grep("IPW", colnames(fit_npcausalML$cv_predictions))])
lrnrs_full <- colnames(fit_npcausalML$cv_predictions)
lrnrs <- gsub("[._]sieve_fourier.+", "", lrnrs_full)
lrnrs <- gsub("_no_sieve", "", lrnrs)
degree <- as.numeric(stringr::str_match(lrnrs_full, "fourier_basis_([0-9]+)")[,2])
degree[grep("no_sieve", lrnrs_full)] <- 0
tmp <- data.table(lrnrs_full, lrnrs , degree, risk = cvrisksDR, risks_oracle = risks_oracle, cvrisksDR = cvrisksDR, cvrisksDRoracle)
gam_keep <- tmp[grep("gam", lrnrs_full),risks_oracle[which.min(risk)], by = degree]$V1
names(gam_keep) <- paste0("Lrnr_gam_cv", "_fourier.basis_", 0:3, "_plugin")
risks_oracle <- c(risks_oracle, gam_keep)
gam_keep <- tmp[grep("gam", lrnrs_full),cvrisksDR[which.min(risk)], by = degree]$V1
names(gam_keep) <- paste0("Lrnr_gam_cv", "_fourier.basis_", 0:3, "_plugin")
cvrisksDR <- c(cvrisksDR, gam_keep)
gam_keep <- tmp[grep("gam", lrnrs_full),cvrisksDRoracle[which.min(risk)], by = degree]$V1
names(gam_keep) <- paste0("Lrnr_gam_cv", "_fourier.basis_", 0:3, "_plugin")
cvrisksDRoracle <- c(cvrisksDRoracle, gam_keep)
sieve_names <- c(colnames(fit_npcausalML$cv_predictions), names(gam_keep))
CATE_library <- c(CATE_library, list(lrnr_gam_sl))
CATEonestepbench <- DR_learner(CATE_library, as.data.frame(W), A, Y, EY1W_est, EY0W_est, pA1W_est, NULL, NULL)
CATEonestepbench <- apply(CATEonestepbench, 2, function(pred) {
mean((pred - CATE)^2)
})
names(CATEonestepbench) <- c(unique(tmp$lrnrs) , "Lrnr_gam_cv")
CATEonestepbenchoracle <- DR_learner(CATE_library, W, A, Y, EY1Wtrue, EY0Wtrue, pA1Wtrue, NULL, NULL)
CATEonestepbenchoracle <- apply(CATEonestepbenchoracle, 2, function(pred) {
mean((pred - CATE)^2)
})
names(CATEonestepbenchoracle) <- c(unique(tmp$lrnrs), "Lrnr_gam_cv")
risk_subst<- apply(subst_CATE, 2, function(pred) {
mean((pred - CATE)^2)
})
risk_subst_cv <- mean((EY1W_est - EY0W_est - CATE)^2)
list(risk_subst_cv = risk_subst_cv, risk_subst = risk_subst, CATEonestepbenchoracle =CATEonestepbenchoracle, CATEonestepbench = CATEonestepbench, sieve =data.frame(sieve_names, cvrisksDRoracle, cvrisksDR, risks_oracle))
}
hard <- hard == "TRUE"
pos <- pos == "TRUE"
n <- as.numeric(n)
simresults <- lapply(1:nsims, function(i){try({
print(i)
onesim(n)
})
})
save(simresults, file = paste0("mainSimResults2/","simsCATE", hard,pos, "n", n, "_gam_highDim"))
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Embedding an R snippet on your website
Add the following code to your website.
For more information on customizing the embed code, read Embedding Snippets.