update plotting code

[ml_measurement_error_public.git] / simulations / plot_example.R

source("RemembR/R/RemembeR.R")
library(arrow)
library(data.table)
library(ggplot2)
library(filelock)
library(argparser)

source("summarize_estimator.R")


parser <- arg_parser("Simulate data and fit corrected models.")
parser <- add_argument(parser, "--infile", default="robustness_2.feather", help="name of the file to read.")
parser <- add_argument(parser, "--remember-file", default="remembr.RDS", help="name of the remember file.")
parser <- add_argument(parser, "--name", default="", help="The name to safe the data to in the remember file.")
args <- parse_args(parser)



## summarize.estimator <- function(df, suffix='naive', coefname='x'){

##     part <- df[,c('N',
##                   'm',
##                   'Bxy',
##                   paste0('B',coefname,'y.est.',suffix),
##                   paste0('B',coefname,'y.ci.lower.',suffix),
##                   paste0('B',coefname,'y.ci.upper.',suffix),
##                   'y_explained_variance',
##                   'Bzx',
##                   'Bzy',
##                   'accuracy_imbalance_difference'
##                   ),
##                with=FALSE]
    
##     true.in.ci <- as.integer((part$Bxy >= part[[paste0('B',coefname,'y.ci.lower.',suffix)]]) & (part$Bxy <= part[[paste0('B',coefname,'y.ci.upper.',suffix)]]))
##     zero.in.ci <- as.integer(0 >= part[[paste0('B',coefname,'y.ci.lower.',suffix)]]) & (0 <= part[[paste0('B',coefname,'y.ci.upper.',suffix)]])
##     bias <- part$Bxy - part[[paste0('B',coefname,'y.est.',suffix)]]
##     sign.correct <- as.integer(sign(part$Bxy) == sign(part[[paste0('B',coefname,'y.est.',suffix)]]))

##     part <- part[,':='(true.in.ci = true.in.ci,
##                        zero.in.ci = zero.in.ci,
##                        bias=bias,
##                        sign.correct =sign.correct)]

##     part.plot <- part[, .(p.true.in.ci = mean(true.in.ci),
##                           mean.bias = mean(bias),
##                           mean.est = mean(.SD[[paste0('B',coefname,'y.est.',suffix)]]),
##                           var.est = var(.SD[[paste0('B',coefname,'y.est.',suffix)]]),
##                           est.upper.95 = quantile(.SD[[paste0('B',coefname,'y.est.',suffix)]],0.95,na.rm=T),
##                           est.lower.95 = quantile(.SD[[paste0('B',coefname,'y.est.',suffix)]],0.05,na.rm=T),
##                           N.sims = .
##                           p.sign.correct = mean(as.integer(sign.correct & (! zero.in.ci))),
##                           variable=coefname,
##                           method=suffix
##                           ),
##                       by=c("N","m",'y_explained_variance','Bzx', 'Bzy', 'accuracy_imbalance_difference')
##                       ]
    
##     return(part.plot)
## }

build_plot_dataset <- function(df){
    
    x.true <-  summarize.estimator(df, 'true','x')

    z.true <-  summarize.estimator(df, 'true','z')

    x.naive <- summarize.estimator(df, 'naive','x')
    
    z.naive <- summarize.estimator(df,'naive','z')

    x.feasible <- summarize.estimator(df, 'feasible', 'x')

    z.feasible <- summarize.estimator(df, 'feasible', 'z')

    x.amelia.full <- summarize.estimator(df, 'amelia.full', 'x')

    z.amelia.full <- summarize.estimator(df, 'amelia.full', 'z')
    
    ## x.mecor <- summarize.estimator(df, 'mecor', 'x')

    ## z.mecor <- summarize.estimator(df, 'mecor', 'z')

    ## x.mecor <- summarize.estimator(df, 'mecor', 'x')

    ## z.mecor <- summarize.estimator(df, 'mecor', 'z')

    x.mle <- summarize.estimator(df, 'mle', 'x')

    z.mle <- summarize.estimator(df, 'mle', 'z')
    
    x.zhang <- summarize.estimator(df, 'zhang', 'x')

    z.zhang <- summarize.estimator(df, 'zhang', 'z')

    x.gmm <- summarize.estimator(df, 'gmm', 'x')

    z.gmm <- summarize.estimator(df, 'gmm', 'z')

    accuracy <- df[,mean(accuracy)]
    plot.df <- rbindlist(list(x.true,z.true,x.naive,z.naive,x.amelia.full,z.amelia.full,x.gmm, z.gmm, x.feasible, z.feasible,z.mle, x.mle, x.zhang, z.zhang, x.gmm, z.gmm),use.names=T)
    plot.df[,accuracy := accuracy]
    plot.df <- plot.df[,":="(sd.est=sqrt(var.est)/N.sims)]
    return(plot.df)
}


sims.df <- read_feather(args$infile)
unique(sims.df[,.N,by=.(N,m)])
print(unique(sims.df$N))

# df <- df[apply(df,1,function(x) !any(is.na(x)))]

if(!('Bzx' %in% names(sims.df)))
    sims.df[,Bzx:=NA]

if(!('accuracy_imbalance_difference' %in% names(sims.df)))
    sims.df[,accuracy_imbalance_difference:=NA]

unique(sims.df[,'accuracy_imbalance_difference'])

change.remember.file(args$remember_file, clear=TRUE)
#plot.df <- build_plot_dataset(df[accuracy_imbalance_difference==0.1][N==700])
plot.df <- build_plot_dataset(sims.df)

remember(plot.df,args$name)

set.remember.prefix(gsub("plot.df.","",args$name))

remember(median(sims.df$cor.xz),'med.cor.xz')
remember(median(sims.df$accuracy),'med.accuracy')
remember(median(sims.df$accuracy.y0),'med.accuracy.y0')
remember(median(sims.df$accuracy.y1),'med.accuracy.y1')
remember(median(sims.df$fpr),'med.fpr')
remember(median(sims.df$fpr.y0),'med.fpr.y0')
remember(median(sims.df$fpr.y1),'med.fpr.y1')
remember(median(sims.df$fnr),'med.fnr')
remember(median(sims.df$fnr.y0),'med.fnr.y0')
remember(median(sims.df$fnr.y1),'med.fnr.y1')

remember(median(sims.df$cor.resid.w_pred),'cor.resid.w_pred')

#ggplot(df,aes(x=Bxy.est.mle)) + geom_histogram() + facet_grid(accuracy_imbalance_difference ~ Bzy)

## ## ## df[gmm.ER_pval<0.05]

## plot.df.test <- plot.df[,':='(method=factor(method,levels=c("Naive","Multiple imputation", "Multiple imputation (Classifier features unobserved)","Regression Calibration","2SLS+gmm","Bespoke MLE", "Feasible"),ordered=T),
##                                    N=factor(N),
##                                    m=factor(m))]

## plot.df.test <- plot.df.test[(variable=='x') & (method!="Multiple imputation (Classifier features unobserved)")]
## p <- ggplot(plot.df.test, aes(y=mean.est, ymax=mean.est + var.est/2, ymin=mean.est-var.est/2, x=method))
## p <- p + geom_hline(data=plot.df.test, mapping=aes(yintercept=0.1),linetype=2)

## p <- p + geom_pointrange() + facet_grid(N~m,as.table=F,scales='free') + scale_x_discrete(labels=label_wrap_gen(4))
## print(p)

## plot.df.test <- plot.df[,':='(method=factor(method,levels=c("Naive","Multiple imputation", "Multiple imputation (Classifier features unobserved)","Regression Calibration","2SLS+gmm","Bespoke MLE", "Feasible"),ordered=T),
##                                    N=factor(N),
##                                    m=factor(m))]

## plot.df.test <- plot.df.test[(variable=='z') & (method!="Multiple imputation (Classifier features unobserved)")]
## p <- ggplot(plot.df.test, aes(y=mean.est, ymax=mean.est + var.est/2, ymin=mean.est-var.est/2, x=method))
## p <- p + geom_hline(data=plot.df.test, mapping=aes(yintercept=-0.1),linetype=2)

## p <- p + geom_pointrange() + facet_grid(m~N,as.table=F,scales='free') + scale_x_discrete(labels=label_wrap_gen(4))
## print(p)


## x.mle <- df[,.(N,m,Bxy.est.mle,Bxy.ci.lower.mle, Bxy.ci.upper.mle, y_explained_variance, Bzx, Bzy, accuracy_imbalance_difference)]
## x.mle.plot <- x.mle[,.(mean.est = mean(Bxy.est.mle),
##                        var.est = var(Bxy.est.mle),
##                        N.sims = .N,
##                        variable='z',
##                        method='Bespoke MLE'
##                        ),
##                     by=c("N","m",'y_explained_variance', 'Bzx', 'Bzy','accuracy_imbalance_difference')]

## z.mle <- df[,.(N,m,Bzy.est.mle,Bzy.ci.lower.mle, Bzy.ci.upper.mle, y_explained_variance, Bzx, Bzy, accuracy_imbalance_difference)]

## z.mle.plot <- z.mle[,.(mean.est = mean(Bzy.est.mle),
##                        var.est = var(Bzy.est.mle),
##                        N.sims = .N,
##                        variable='z',
##                        method='Bespoke MLE'
##                        ),
##                     by=c("N","m",'y_explained_variance','Bzx')]

## plot.df <- z.mle.plot
## plot.df.test <- plot.df[,':='(method=factor(method,levels=c("Naive","Multiple imputation", "Multiple imputation (Classifier features unobserved)","Regression Calibration","2SLS+gmm","Bespoke MLE", "Feasible"),ordered=T),
##                                    N=factor(N),
##                                    m=factor(m))]

## plot.df.test <- plot.df.test[(variable=='z') & (m != 1000) & (m!=500) & (method!="Multiple imputation (Classifier features unobserved)")]
## p <- ggplot(plot.df.test, aes(y=mean.est, ymax=mean.est + var.est/2, ymin=mean.est-var.est/2, x=method))
## p <- p + geom_hline(aes(yintercept=0.2),linetype=2)

## p <- p + geom_pointrange() + facet_grid(m~Bzx, Bzy,as.table=F) + scale_x_discrete(labels=label_wrap_gen(4))
## print(p)


## ## ggplot(plot.df[variable=='x'], aes(y=mean.est, ymax=mean.est + var.est/2, ymin=mean.est-var.est/2, x=method)) + geom_pointrange() + facet_grid(-m~N) + scale_x_discrete(labels=label_wrap_gen(10))

## ## ggplot(plot.df,aes(y=N,x=m,color=p.sign.correct)) + geom_point() + facet_grid(variable ~ method) + scale_color_viridis_c(option='D') + theme_minimal() + xlab("Number of gold standard labels") + ylab("Total sample size") 

## ## ggplot(plot.df,aes(y=N,x=m,color=abs(mean.bias))) + geom_point() + facet_grid(variable ~ method) + scale_color_viridis_c(option='D') + theme_minimal() + xlab("Number of gold standard labels") + ylab("Total sample size")