comparison quantp.r @ 1:dec87511835e draft

planemo upload commit 1887dff812162880d66b003a927867cd5000c98f

0:f1db758949f4

  tempdf[is.na(tempdf)] = 0;
  tempdf$Group = tempgrp;
  png(outfile, width = 6, height = 6, units = 'in', res=300);
  # bitmap(outfile, "png16m");
  g = autoplot(prcomp(select(tempdf, -Group)), data = tempdf, colour = 'Group', size=3);
  plot(g);
  dev.off();
}

#===============================================================================

  rownames(PE_TE_data) = PE_TE_data$PE_ID;
  regmodel = lm(PE_abundance~TE_abundance, data=PE_TE_data);
  regmodel_summary = summary(regmodel);
  
  cat("<font><h3>Linear Regression model fit between Proteome and Transcriptome data</h3></font>\n",
    "<p>Assuming a linear relationship between Proteome and Transcriptome data, we here fit a linear regression model.</p>\n",
    '<table  border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Parameter</font></th><th><font color=#ffcc33>Value</font></th></tr>\n',
    file = htmloutfile, append = TRUE);
  
  cat("<tr><td>Formula</td><td>","PE_abundance~TE_abundance","</td></tr>\n",
    "<tr><td colspan='2' align='center'> <b>Coefficients</b></td>","</tr>\n",
    "<tr><td>",names(regmodel$coefficients[1]),"</td><td>",regmodel$coefficients[1]," (Pvalue:", regmodel_summary$coefficients[1,4],")","</td></tr>\n",
    "<tr><td>",names(regmodel$coefficients[2]),"</td><td>",regmodel$coefficients[2]," (Pvalue:", regmodel_summary$coefficients[2,4],")","</td></tr>\n",
    "<tr><td colspan='2' align='center'> <b>Model parameters</b></td>","</tr>\n",
    "<tr><td>Residual standard error</td><td>",regmodel_summary$sigma," (",regmodel_summary$df[2]," degree of freedom)</td></tr>\n",
    "<tr><td>F-statistic</td><td>",regmodel_summary$fstatistic[1]," ( on ",regmodel_summary$fstatistic[2]," and  ",regmodel_summary$fstatistic[3]," degree of freedom)</td></tr>\n",
    "<tr><td>R-squared</td><td>",regmodel_summary$r.squared,"</td></tr>\n",
    "<tr><td>Adjusted R-squared</td><td>",regmodel_summary$adj.r.squared,"</td></tr>\n",
    file = htmloutfile, append = TRUE);
  
  cat("</table>\n", file = htmloutfile, append = TRUE);
  
  cat(
    "<font color='#ff0000'><h3>Regression and diagnostics plots</h3></font>\n",

  # bitmap(outplot, "png16m");
  par(mfrow=c(1,1));
  plot(regmodel, 1, cex.lab=1.5);
  dev.off();
  
  outplot = paste(outdir,"/PE_TE_lm_2.png",sep="",collapse="");
  png(outplot,width = 10, height = 10, units = 'in', res=300);
  # bitmap(outplot, "png16m");
  par(mfrow=c(1,1));
  plot(regmodel, 2, cex.lab=1.5);
  dev.off();
  
  outplot = paste(outdir,"/PE_TE_lm_5.png",sep="",collapse="");
  png(outplot, width = 10, height = 10, units = 'in',res=300);
  # bitmap(outplot, "png16m");
  par(mfrow=c(1,1));
  plot(regmodel, 5, cex.lab=1.5);
  dev.off();
  
  cat('<table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; ">', file = htmloutfile, append = TRUE);
  
    cat(
    '<tr bgcolor="#7a0019"><th>', "<font color='#ffcc33'><h4>1) <u>Residuals vs Fitted plot</h4></font></u></th>\n",
    '<th><font color=#ffcc33><h4>2) <u>Normal Q-Q plot of residuals</h4></font></u></th></tr>\n',
    file = htmloutfile, append = TRUE);
  
  cat(
    '<tr><td align=center><img src="PE_TE_lm_1.png" width=600 height=600></td><td align=center><img src="PE_TE_lm_2.png" width=600 height=600></td></tr>\n',
    file = htmloutfile, append = TRUE);
  
  cat(
    '<tr><td align=center>This plot checks for linear relationship assumptions.<br>If a horizontal line is observed without any distinct patterns, it indicates a linear relationship.</td>\n',
    '<td align=center>This plot checks whether residuals are normally distributed or not.<br>It is good if the residuals points follow the straight dashed line i.e., do not deviate much from dashed line.</td></tr></table>\n',
    file = htmloutfile, append = TRUE);
    
    
    #@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
    # Residuals data
    #@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
    res_all = regmodel$residuals;
    res_mean = mean(res_all);
    res_sd = sd(res_all);
    res_diff = (res_all-res_mean);
    res_zscore = res_diff/res_sd;
    # res_outliers = res_all[which((res_zscore > 2)|(res_zscore < -2))]
    
    
    tempind = which((res_zscore > 2)|(res_zscore < -2));
    res_PE_TE_data_no_outlier = PE_TE_data[-tempind,];
    res_PE_TE_data_no_outlier$residuals = res_all[-tempind];
    res_PE_TE_data_outlier = PE_TE_data[tempind,];
    res_PE_TE_data_outlier$residuals = res_all[tempind];
  
  # Save the complete table for download (influential_observations)
    temp_outlier_data = data.frame(res_PE_TE_data_outlier$PE_ID, res_PE_TE_data_outlier$TE_abundance, res_PE_TE_data_outlier$PE_abundance, res_PE_TE_data_outlier$residuals)
    colnames(temp_outlier_data) = c("Gene", "Transcript abundance", "Protein abundance", "Residual value")
    outdatafile = paste(outdir,"/PE_TE_outliers_residuals.txt", sep="", collapse="");
    write.table(temp_outlier_data, file=outdatafile, row.names=F, sep="\t", quote=F);
  
  
  # Save the complete table for download (non influential_observations)
    temp_all_data = data.frame(PE_TE_data$PE_ID, PE_TE_data$TE_abundance, PE_TE_data$PE_abundance, res_all)
    colnames(temp_all_data) = c("Gene", "Transcript abundance", "Protein abundance", "Residual value")
    outdatafile = paste(outdir,"/PE_TE_abundance_residuals.txt", sep="", collapse="");
    write.table(temp_all_data, file=outdatafile, row.names=F, sep="\t", quote=F);
  
  
  cat('<br><h2 id="inf_obs"><font color=#ff0000>Outliers based on the residuals from regression analysis</font></h2>\n',
    file = htmloutfile, append = TRUE);
  cat('<table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; ">\n',
  '<tr bgcolor="#7a0019"><th colspan=2><font color=#ffcc33>Residuals from Regression</font></th></tr>\n',
   '<tr bgcolor="#7a0019"><th><font color=#ffcc33>Parameter</font></th><th><font color=#ffcc33>Value</font></th></tr>\n',
    file = htmloutfile, append = TRUE);
    
  cat("<tr><td>Mean Residual value</td><td>",res_mean,"</td></tr>\n",
    "<tr><td>Standard deviation (Residuals)</td><td>",res_sd,"</td></tr>\n",
    '<tr><td>Total outliers (Residual value > 2 standard deviation from the mean)</td><td>',length(tempind),' <font size=4>(<b><a href=PE_TE_outliers_residuals.txt target="_blank">Download these ',length(tempind),' data points with high residual values here</a></b>)</font></td>\n',
    '<tr><td colspan=2 align=center><font size=4>(<b><a href=PE_TE_abundance_residuals.txt target="_blank">Download the complete residuals data here</a></b>)</font></td></td>\n',
    "</table><br><br>\n",
    file = htmloutfile, append = TRUE);
    
  #@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
    
    
  cat('<br><br><table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; ">', file = htmloutfile, append = TRUE);

  cat(
    '<tr bgcolor="#7a0019"><th><font color=#ffcc33><h4>3) <u>Residuals vs Leverage plot</h4></font></u></th></tr>\n',
    file = htmloutfile, append = TRUE);
  
  cat(
    '<tr><td align=center><img src="PE_TE_lm_5.png" width=600 height=600></td></tr>\n',
    file = htmloutfile, append = TRUE);
  
  cat(
    '<tr><td align=center>This plot is useful to identify any influential cases, that is outliers or extreme values.<br>They might influence the regression results upon inclusion or exclusion from the analysis.</td></tr></table><br>\n',
    file = htmloutfile, append = TRUE);

  
  #^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
  # Cook's Distance
  #^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
  cat('<hr/><h2 id="inf_obs"><font color=#ff0000>INFLUENTIAL OBSERVATIONS</font></h2>\n',
    file = htmloutfile, append = TRUE);
  cat(
    '<p><b>Cook\'s distance</b> computes the influence of each data point/observation on the predicted outcome. i.e. this measures how much the observation is influencing the fitted values.<br>In general use, those observations that have a <b>Cook\'s distance > than ', cookdist_upper_cutoff,' times the mean</b> may be classified as <b>influential.</b></p>\n',
    file = htmloutfile, append = TRUE);
  
  cooksd <- cooks.distance(regmodel);

  points(sel_nonoutlier, cooksd[sel_nonoutlier],pch="*", cex=2, cex.lab=1.5, col="black")
  abline(h = as.numeric(cookdist_upper_cutoff)*mean(cooksd, na.rm=T), col="red")  # add cutoff line
  #text(x=1:length(cooksd)+1, y=cooksd, labels=ifelse(cooksd>as.numeric(cookdist_upper_cutoff)*mean(cooksd, na.rm=T),names(cooksd),""), col="red", pos=2)  # add labels
  dev.off();
  
  cat(
    '<img src="PE_TE_lm_cooksd.png" width=800 height=800>',
    '<br>In the above plot, observations above red line (',cookdist_upper_cutoff,' * mean Cook\'s distance) are influential. Genes that are outliers could be important. These observations influences the correlation values and regression coefficients<br><br>',
    file = htmloutfile, append = TRUE);    

  tempind = which(cooksd>as.numeric(cookdist_upper_cutoff)*mean(cooksd, na.rm=T));
  PE_TE_data_no_outlier = PE_TE_data[-tempind,];
  PE_TE_data_no_outlier$cooksd = cooksd[-tempind];
  PE_TE_data_outlier = PE_TE_data[tempind,];
  PE_TE_data_outlier$cooksd = cooksd[tempind];

  cat(
    '<table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Parameter</font></th><th><font color=#ffcc33>Value</font></th></tr>\n',
    file = htmloutfile, append = TRUE);
  
  # Save the complete table for download (influential_observations)
    temp_outlier_data = data.frame(PE_TE_data_outlier$PE_ID, PE_TE_data_outlier$TE_abundance, PE_TE_data_outlier$PE_abundance, PE_TE_data_outlier$cooksd)
    colnames(temp_outlier_data) = c("Gene", "Transcript abundance", "Protein abundance", "Cook's distance")
    outdatafile = paste(outdir,"/PE_TE_influential_observation.txt", sep="", collapse="");
    write.table(temp_outlier_data, file=outdatafile, row.names=F, sep="\t", quote=F);
  
  
  # Save the complete table for download (non influential_observations)
    temp_no_outlier_data = data.frame(PE_TE_data_no_outlier$PE_ID, PE_TE_data_no_outlier$TE_abundance, PE_TE_data_no_outlier$PE_abundance, PE_TE_data_no_outlier$cooksd)
    colnames(temp_no_outlier_data) = c("Gene", "Transcript abundance", "Protein abundance", "Cook's distance")
    outdatafile = paste(outdir,"/PE_TE_non_influential_observation.txt", sep="", collapse="");
    write.table(temp_no_outlier_data, file=outdatafile, row.names=F, sep="\t", quote=F);
  
  
  cat("<tr><td>Mean Cook\'s distance</td><td>",mean(cooksd, na.rm=T),"</td></tr>\n",
    "<tr><td>Total influential observations (Cook\'s distance > ",cookdist_upper_cutoff," * mean Cook\'s distance)</td><td>",length(tempind),"</td>\n",
    
    "<tr><td>Observations with Cook\'s distance < ",cookdist_upper_cutoff," * mean Cook\'s distance</td><td>",length(which(cooksd<as.numeric(cookdist_upper_cutoff)*mean(cooksd, na.rm=T))),"</td>\n",
    "</table><br><br>\n",
    file = htmloutfile, append = TRUE);
    
    
    #@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
    # Scatter plot after removal of influential points
    #@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
    outplot = paste(outdir,"/AbundancePlot_scatter_without_outliers.png",sep="",collapse="");
    min_lim = min(c(PE_TE_data$PE_abundance,PE_TE_data$TE_abundance));
    max_lim = max(c(PE_TE_data$PE_abundance,PE_TE_data$TE_abundance));
    png(outplot, width = 10, height = 10, units = 'in', res=300);
    # bitmap(outplot,"png16m");
    g = ggplot(PE_TE_data_no_outlier, aes(x=TE_abundance, y=PE_abundance))+geom_point() + geom_smooth() + xlab("Transcript abundance log fold-change") + ylab("Protein abundance log fold-change") + xlim(min_lim,max_lim) + ylim(min_lim,max_lim);
    suppressMessages(plot(g));
    dev.off();
    
    cat('<table  border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Scatterplot: Before removal</font></th><th><font color=#ffcc33>Scatterplot: After removal</font></th></tr>\n', file = htmloutfile, append = TRUE);
    # Before
    cat("<tr><td align=center><!--<font color='#ff0000'><h3>Scatter plot between Proteome and Transcriptome Abundance</h3></font>\n-->", '<img src="TE_PE_scatter.png" width=600 height=600></td>\n', file = htmloutfile, append = TRUE);
    
    # After
    cat("<td align=center>\n",
    '<img src="AbundancePlot_scatter_without_outliers.png" width=600 height=600></td></tr>\n',
    file = htmloutfile, append = TRUE);
    #@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
    
  
  cor_result_pearson = cor.test(PE_TE_data_no_outlier[,"TE_abundance"], PE_TE_data_no_outlier[,"PE_abundance"], method = "pearson");
  cor_result_spearman = cor.test(PE_TE_data_no_outlier[,"TE_abundance"], PE_TE_data_no_outlier[,"PE_abundance"], method = "spearman");
  cor_result_kendall = cor.test(PE_TE_data_no_outlier[,"TE_abundance"], PE_TE_data_no_outlier[,"PE_abundance"], method = "kendall");
  

  singlesample_cor(PE_TE_data, htmloutfile, append=TRUE);
  cat('</td>\n', file = htmloutfile, append=TRUE);
  
  
  cat('<td><table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Parameter</font></th><th><font color=#ffcc33>Method 1</font></th><th><font color=#ffcc33>Method 2</font></th><th><font color=#ffcc33>Method 3</font></th></tr>\n',
    file = htmloutfile, append = TRUE);
  
  cat(
    "<tr><td>Correlation method</td><td>",cor_result_pearson$method,"</td><td>",cor_result_spearman$method,"</td><td>",cor_result_kendall$method,"</td></tr>\n",
    "<tr><td>Correlation coefficient</td><td>",cor_result_pearson$estimate,"</td><td>",cor_result_spearman$estimate,"</td><td>",cor_result_kendall$estimate,"</td></tr>\n",
    file = htmloutfile, append = TRUE)

  }else{
    tab_n_row = 10;
  }
  
  cat("<br><br><font size=5><b><a href='PE_TE_influential_observation.txt' target='_blank'>Download the complete list of influential observations</a></b></font>&nbsp;&nbsp;&nbsp;&nbsp;",
  "<font size=5><b><a href='PE_TE_non_influential_observation.txt' target='_blank'>Download the complete list (After removing influential points)</a></b></font><br>\n",
  '<br><font color="brown"><h4>Top ',as.character(tab_n_row),' Influential observations (Cook\'s distance > ',cookdist_upper_cutoff,' * mean Cook\'s distance)</h4></font>\n',
    file = htmloutfile, append = TRUE);
  
  cat('<table border=1 cellspacing=0 cellpadding=5> <tr bgcolor="#7a0019">\n', sep = "",file = htmloutfile, append = TRUE);
  cat("<th><font color=#ffcc33>Gene</font></th><th><font color=#ffcc33>Protein Log Fold-Change</font></th><th><font color=#ffcc33>Transcript Log Fold-Change</font></th><th><font color=#ffcc33>Cook's Distance</font></th></tr>\n",
    file = htmloutfile, append = TRUE);
  
  
  for(i in 1:tab_n_row)
  {
    cat(

      '<td>',format(PE_TE_data_outlier_sorted[i,2], scientific=F),'</td>\n',
      '<td>',PE_TE_data_outlier_sorted[i,4],'</td>\n',
      '<td>',format(PE_TE_data_outlier_sorted[i,5], scientific=F),'</td></tr>\n',
      file = htmloutfile, append = TRUE);
  }
    cat('</table><br><br>\n',file = htmloutfile, append = TRUE);
    
    
}



#===============================================================================
# Heatmap
#===============================================================================
singlesample_heatmap=function(PE_TE_data, htmloutfile, hm_nclust){
  cat('<br><table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Heatmap of PE and TE abundance values (Hierarchical clustering)</font></th><th><font color=#ffcc33>Number of clusters to extract: ',hm_nclust,'</font></th></tr>\n',
    file = htmloutfile, append = TRUE);
  
  hc=hclust(dist(as.matrix(PE_TE_data[,c("PE_abundance","TE_abundance")])))
  hm_cluster = cutree(hc,k=hm_nclust);
  
  outplot = paste(outdir,"/PE_TE_heatmap.png",sep="",collapse="");
  png(outplot, width = 10, height = 10, units = 'in', res=300);
  # bitmap(outplot, "png16m");
  par(mfrow=c(1,1));
  hmap = heatmap.2(as.matrix(PE_TE_data[,c("PE_abundance","TE_abundance")]), trace="none", cexCol=1, col=greenred(100),Colv=F, labCol=c("Proteins","Transcripts"), scale="col", hclustfun = hclust, distfun = dist);
  dev.off();
  
  cat('<tr><td align=center colspan="2"><img src="PE_TE_heatmap.png" width=800 height=800></td></tr>\n',
    file = htmloutfile, append = TRUE);
  
  
  temp_PE_TE_data = data.frame(PE_TE_data$PE_ID, PE_TE_data$TE_abundance, PE_TE_data$PE_abundance, hm_cluster);
  colnames(temp_PE_TE_data) = c("Gene", "Transcript abundance", "Protein abundance", "Cluster (Hierarchical clustering)")
  tempoutfile = paste(outdir,"/PE_TE_hc_clusterpoints.txt",sep="",collapse="");
  write.table(temp_PE_TE_data, file=tempoutfile, row.names=F, quote=F, sep="\t", eol="\n")
  
  
  cat('<tr><td colspan="2" align=center><font size=5><a href="PE_TE_hc_clusterpoints.txt" target="_blank"><b>Download the hierarchical cluster list</b></a></font></td></tr></table>\n',
    file = htmloutfile, append = TRUE);
}


#===============================================================================
# K-means clustering

  # bitmap(outplot, "png16m");
  par(mfrow=c(1,1));
  scatter.smooth(PE_TE_data_kdata[,"TE_abundance"], PE_TE_data_kdata[,"PE_abundance"], xlab="Transcript Abundance", ylab="Protein Abundance", cex.lab=1.5);
  legend(1, 95, legend=c("Cluster 1", "Line 2"), col="red", lty=1:1, cex=0.8)
  legend(1, 95, legend="Cluster 2", col="green", lty=1:1, cex=0.8)
  
  
  ind=which(k1$cluster==1);
  points(PE_TE_data_kdata[ind,"TE_abundance"], PE_TE_data_kdata[ind,"PE_abundance"], col="red", pch=16);
  ind=which(k1$cluster==2);
  points(PE_TE_data_kdata[ind,"TE_abundance"], PE_TE_data_kdata[ind,"PE_abundance"], col="green", pch=16);

  points(PE_TE_data_kdata[ind,"TE_abundance"], PE_TE_data_kdata[ind,"PE_abundance"], col="yellow", pch=16);
  ind=which(k1$cluster==10);
  points(PE_TE_data_kdata[ind,"TE_abundance"], PE_TE_data_kdata[ind,"PE_abundance"], col="orange", pch=16);
  dev.off();
  
  cat('<br><br><table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>K-mean clustering</font></th><th><font color=#ffcc33>Number of clusters: ',nclust,'</font></th></tr>\n',
    file = htmloutfile, append = TRUE);
  
  tempind = order(k1$cluster);
  tempoutfile = paste(outdir,"/PE_TE_kmeans_clusterpoints.txt",sep="",collapse="");
  write.table(data.frame(PE_TE_data_kdata[tempind, ], Cluster=k1$cluster[tempind]), file=tempoutfile, row.names=F, quote=F, sep="\t", eol="\n")
  
  
  cat('<tr><td colspan="2" align=center><img src="PE_TE_kmeans.png" width=800 height=800></td></tr>\n',
    file = htmloutfile, append = TRUE);
  cat('<tr><td colspan="2" align=center><font size=5><a href="PE_TE_kmeans_clusterpoints.txt" target="_blank"><b>Download the cluster list</b></a></font></td></tr></table><br><hr/>\n',
    file = htmloutfile, append = TRUE);
  
}

#===============================================================================
# scatter plot

{
  min_lim = min(c(PE_TE_data$PE_abundance,PE_TE_data$TE_abundance));
  max_lim = max(c(PE_TE_data$PE_abundance,PE_TE_data$TE_abundance));
  png(outfile, width = 10, height = 10, units = 'in', res=300);
  # bitmap(outfile, "png16m");
  g = ggplot(PE_TE_data, aes(x=TE_abundance, y=PE_abundance))+geom_point() + geom_smooth() + xlab("Transcript abundance log fold-change") + ylab("Protein abundance log fold-change") + xlim(min_lim,max_lim) + ylim(min_lim,max_lim);
  suppressMessages(plot(g));
  # plot(g);
  dev.off();
}

#===============================================================================
# Correlation table

  tempdf = df[,-1, drop=FALSE];
  tempdf = t(tempdf) %>% as.data.frame();
  tempdf[is.na(tempdf)] = 0;
  tempdf$Sample = rownames(tempdf);
  tempdf1 = melt(tempdf, id.vars = "Sample");
  tempdf1$Group = sampleinfo_df[tempdf1$Sample,2];
  png(outplot, width = 6, height = 6, units = 'in', res=300);
  # bitmap(outplot, "png16m");
  if(fill_leg=="Yes")
  {
    g = ggplot(tempdf1, aes(x=Sample, y=value, fill=Group)) + geom_boxplot() + labs(x=user_xlab) + labs(y=user_ylab)
  }else{
    if(fill_leg=="No")
    {
      tempdf1$Group = c("case", "control")
      g = ggplot(tempdf1, aes(x=Sample, y=value, fill=Group)) + geom_boxplot() + labs(x=user_xlab) + labs(y=user_ylab)
    }
  }
  plot(g);
  dev.off();
}


#===============================================================================
# Mean or Median of Replicates
#===============================================================================

mergeReplicates = function(TE_df,PE_df, sampleinfo_df, method)
{
grps = unique(sampleinfo_df[,2]);

TE_df_merged <<- sapply(grps, function(x){
  tempsample = sampleinfo_df[which(sampleinfo_df$Group==x),1]
  if(length(tempsample)!=1){
    apply(TE_df[,tempsample],1,method);
  }else{
    return(TE_df[,tempsample]);
  }
});
TE_df_merged <<-   data.frame(as.character(TE_df[,1]), TE_df_merged);
colnames(TE_df_merged) = c(colnames(TE_df)[1], grps);

PE_df_merged <<- sapply(grps, function(x){
  tempsample = sampleinfo_df[which(sampleinfo_df$Group==x),1]
  if(length(tempsample)!=1){
    apply(PE_df[,tempsample],1,method);
  }else{
    return(PE_df[,tempsample]);
  }
});

PE_df_merged <<-   data.frame(as.character(PE_df[,1]), PE_df_merged);
colnames(PE_df_merged) = c(colnames(PE_df)[1], grps);

#sampleinfo_df_merged =  data.frame(Sample = grps, Group = grps, stringsAsFactors = F);
sampleinfo_df_merged =  data.frame(Sample = grps, Group = "Group", stringsAsFactors = F);

return(list(TE_df_merged = TE_df_merged, PE_df_merged = PE_df_merged, sampleinfo_df_merged = sampleinfo_df_merged));
}

#===============================================================================
# (T-Test or Wilcoxon ranksum test) and Volcano Plot
#===============================================================================

perform_Test_Volcano = function(TE_df_data,PE_df_data,TE_df_logfold, PE_df_logfold,sampleinfo_df, method, correction_method,volc_with)
{

PE_colnames = colnames(PE_df_data);
control_sample = sampleinfo_df[which(sampleinfo_df$Group=="control"),1];
control_ind <<- sapply(control_sample, function(x){temp_ind = which(PE_colnames==x); as.numeric(temp_ind)});
condition_sample = sampleinfo_df[which(sampleinfo_df$Group=="case"),1];
condition_ind <<- sapply(condition_sample, function(x){temp_ind = which(PE_colnames==x); as.numeric(temp_ind)});

if(method=="mean"){
  #PE_pval = apply(PE_df_data[2:length(colnames(PE_df_data))],1,function(x) t.test(x[condition_ind-1], x[control_ind-1])$p.value);
  PE_pval = apply(PE_df_data[2:length(colnames(PE_df_data))],1,function(x) {obj<-try(t.test(x[condition_ind-1], x[control_ind-1]),silent=TRUE); if(is(obj, "try-error")){return(NA)}else{return(obj$p.value)}})
}else{
if(method=="median"){
    PE_pval = apply(PE_df_data[2:length(colnames(PE_df_data))],1,function(x) {obj<-try(wilcox.test(x[condition_ind-1], x[control_ind-1]),silent=TRUE); if(is(obj, "try-error")){return(NA)}else{return(obj$p.value)}})
    # PE_pval = apply(PE_df_data[2:length(colnames(PE_df_data))],1,function(x) wilcox.test(x[condition_ind-1], x[control_ind-1])$p.value);
  }
}
PE_adj_pval = p.adjust(PE_pval, method = correction_method, n = length(PE_pval))


TE_colnames = colnames(TE_df_data);
control_sample = sampleinfo_df[which(sampleinfo_df$Group=="control"),1];
control_ind <<- sapply(control_sample, function(x){temp_ind = which(TE_colnames==x); as.numeric(temp_ind)});
condition_sample = sampleinfo_df[which(sampleinfo_df$Group=="case"),1];
condition_ind <<- sapply(condition_sample, function(x){temp_ind = which(TE_colnames==x); as.numeric(temp_ind)});

if(method=="mean"){
  # TE_pval = apply(TE_df_data[2:length(colnames(TE_df_data))],1,function(x) t.test(x[condition_ind-1], x[control_ind-1])$p.value);
  TE_pval = apply(TE_df_data[2:length(colnames(TE_df_data))],1,function(x) {obj<-try(t.test(x[condition_ind-1], x[control_ind-1]),silent=TRUE); if(is(obj, "try-error")){return(NA)}else{return(obj$p.value)}})
}else{
  if(method=="median"){
  TE_pval = apply(TE_df_data[2:length(colnames(TE_df_data))],1,function(x) {obj<-try(wilcox.test(x[condition_ind-1], x[control_ind-1]),silent=TRUE); if(is(obj, "try-error")){return(NA)}else{return(obj$p.value)}})
  # TE_pval = apply(TE_df_data[2:length(colnames(TE_df_data))],1,function(x) wilcox.test(x[condition_ind-1], x[control_ind-1])$p.value);
  }
}
TE_adj_pval = p.adjust(TE_pval, method = correction_method, n = length(TE_pval))


PE_TE_logfold_pval = data.frame(TE_df_logfold$Gene, TE_df_logfold$LogFold, TE_pval, TE_adj_pval, PE_df_logfold$LogFold, PE_pval, PE_adj_pval);
colnames(PE_TE_logfold_pval) = c("Gene", "Transcript log fold-change", "p-value (transcript)", "adj p-value (transcript)", "Protein log fold-change", "p-value (protein)", "adj p-value (protein)");
outdatafile = paste(outdir,"/PE_TE_logfold_pval.txt", sep="", collapse="");
write.table(PE_TE_logfold_pval, file=outdatafile, row.names=F, sep="\t", quote=F);
cat("<br><br><font size=5><b><a href='PE_TE_logfold_pval.txt' target='_blank'>Download the complete fold change data here</a></b></font><br>\n",
    file = htmloutfile, append = TRUE);

    if(length(condition_ind)!=1)
        {
        # Volcano Plot

        if(volc_with=="adj_pval")
        {
            PE_pval = PE_adj_pval
            TE_pval = TE_adj_pval
            volc_ylab = "-log10 Adjusted p-value";
        }else{
          if(volc_with=="pval")
          {
            volc_ylab = "-log10 p-value";
          }
        }
        outplot = paste(outdir,"/PE_volcano.png",sep="",collapse="");
          png(outplot, width = 10, height = 10, units = 'in', res=300);
          # bitmap(outplot, "png16m");
          par(mfrow=c(1,1));
  
        plot(PE_df_logfold$LogFold, -log10(PE_pval),
             xlab="log2 fold change", ylab=volc_ylab,
             type="n")
        sel <- which((PE_df_logfold$LogFold<=log(2,base=2))&(PE_df_logfold$LogFold>=log(0.5, base=2))) # or whatever you want to use
        points(PE_df_logfold[sel,"LogFold"], -log10(PE_pval[sel]),col="black")
        #sel <- which((PE_df_logfold$LogFold>log(2,base=2))&(PE_df_logfold$LogFold<log(0.5,base=2))) # or whatever you want to use
        sel <- which((PE_df_logfold$LogFold>log(2,base=2))|(PE_df_logfold$LogFold<log(0.5, base=2)))
        sel1 <- which(PE_pval<=0.05)
        sel=intersect(sel,sel1)
        points(PE_df_logfold[sel,"LogFold"], -log10(PE_pval[sel]),col="red")
        sel <- which((PE_df_logfold$LogFold>log(2,base=2))|(PE_df_logfold$LogFold<log(0.5, base=2)))
        sel1 <- which(PE_pval>0.05)
        sel=intersect(sel,sel1)
        points(PE_df_logfold[sel,"LogFold"], -log10(PE_pval[sel]),col="blue")
        abline(h = -log(0.05,base=10), col="red", lty=2)
        abline(v = log(2,base=2), col="red", lty=2)
        abline(v = log(0.5,base=2), col="red", lty=2)
        dev.off();
  


        outplot = paste(outdir,"/TE_volcano.png",sep="",collapse="");
          png(outplot, width = 10, height = 10, units = 'in', res=300);
          # bitmap(outplot, "png16m");
          par(mfrow=c(1,1));

        plot(TE_df_logfold$LogFold, -log10(TE_pval),
             xlab="log2 fold change", ylab=volc_ylab,
             type="n")
        sel <- which((TE_df_logfold$LogFold<=log(2,base=2))&(TE_df_logfold$LogFold>=log(0.5, base=2))) # or whatever you want to use
        points(TE_df_logfold[sel,"LogFold"], -log10(TE_pval[sel]),col="black")
        #sel <- which((TE_df_logfold$LogFold>log(2,base=2))&(TE_df_logfold$LogFold<log(0.5,base=2))) # or whatever you want to use
        sel <- which((TE_df_logfold$LogFold>log(2,base=2))|(TE_df_logfold$LogFold<log(0.5, base=2)))
        sel1 <- which(TE_pval<=0.05)
        sel=intersect(sel,sel1)
        points(TE_df_logfold[sel,"LogFold"], -log10(TE_pval[sel]),col="red")
        sel <- which((TE_df_logfold$LogFold>log(2,base=2))|(TE_df_logfold$LogFold<log(0.5, base=2)))
        sel1 <- which(TE_pval>0.05)
        sel=intersect(sel,sel1)
        points(TE_df_logfold[sel,"LogFold"], -log10(TE_pval[sel]),col="blue")
        abline(h = -log(0.05,base=10), col="red", lty=2)
        abline(v = log(2,base=2), col="red", lty=2)
        abline(v = log(0.5,base=2), col="red", lty=2)
        dev.off();



        cat('<br><table  border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Transcript Fold-Change</font></th><th><font color=#ffcc33>Protein Fold-Change</font></th></tr>\n', file = htmloutfile, append = TRUE);
            cat("<tr><td align=center>", '<img src="TE_volcano.png" width=600 height=600></td>\n', file = htmloutfile, append = TRUE);
            cat("<td align=center>",
            '<img src="PE_volcano.png" width=600 height=600></td></tr></table><br>\n',
            file = htmloutfile, append = TRUE);
    }else{
        cat('<br><br><b><font color=red>!!! No replicates found. Cannot perform test to check significance of differential expression. Thus, no Volcano plot generated !!!</font></b><br><br>',
        file = htmloutfile, append = TRUE);
    }

}


#***************************************************************************************************************************************
# Functions: End
#***************************************************************************************************************************************




#===============================================================================
# Arguments
#===============================================================================

volc_with = args[10];

htmloutfile = args[11]; # html output file
outdir = args[12]; # html supporting files


#===============================================================================
# Check for file existance
#===============================================================================
if(! file.exists(proteome_file))
{

suppressPackageStartupMessages(library(dplyr));
suppressPackageStartupMessages(library(data.table));
suppressPackageStartupMessages(library(gplots));
suppressPackageStartupMessages(library(ggplot2));
suppressPackageStartupMessages(library(ggfortify));

#===============================================================================
# Select mode and parse experiment design file
#===============================================================================
if(mode=="multiple")
{
    expDesign = fread(sampleinfo_file, header = FALSE, stringsAsFactors = FALSE, sep="\t") %>% data.frame();
    expDesign_cc = expDesign[1:2,];
    
    sampleinfo_df = expDesign[3:nrow(expDesign),];
    rownames(sampleinfo_df)=1:nrow(sampleinfo_df);
    colnames(sampleinfo_df) =  c("Sample","Group");
    
    condition_cols = sampleinfo_df[which(sampleinfo_df[,2]==expDesign_cc[which(expDesign_cc[,1]=="case"),2]),1];
    condition_g_name = "case";
    control_cols = sampleinfo_df[which(sampleinfo_df[,2]==expDesign_cc[which(expDesign_cc[,1]=="control"),2]),1];
    control_g_name = "control";
    sampleinfo_df[which(sampleinfo_df[,2]==expDesign_cc[which(expDesign_cc[,1]=="case"),2]),2] = "case";
    sampleinfo_df[which(sampleinfo_df[,2]==expDesign_cc[which(expDesign_cc[,1]=="control"),2]),2] = "control";
    sampleinfo_df_orig = sampleinfo_df;
}

if(mode=="logfold")
{
    sampleinfo_df = data.frame("Sample"= c("LogFold"), "Group"=c("Fold_Change"))
}

#===============================================================================
# Parse Transcriptome data
#===============================================================================
TE_df_orig = fread(transcriptome_file, sep="\t", stringsAsFactor=F, header=T) %>% data.frame();
if(mode=="multiple")
{
    TE_df = TE_df_orig[,c(colnames(TE_df_orig)[1],condition_cols,control_cols)];
}
if(mode=="logfold")
{
    TE_df = TE_df_orig;
    colnames(TE_df) = c("Genes", "LogFold");
}
#===============================================================================
# Parse Proteome data
#===============================================================================
PE_df_orig = fread(proteome_file, sep="\t", stringsAsFactor=F, header=T) %>% data.frame();
if(mode=="multiple")
{
    PE_df = PE_df_orig[,c(colnames(PE_df_orig)[1],condition_cols,control_cols)];
}
if(mode=="logfold")
{
    PE_df = PE_df_orig;
    colnames(PE_df) = c("Genes", "LogFold");
}

#=============================================================================================================
# Create directory structures and then set the working directory to output directory
#=============================================================================================================

  dir.create(outdir);
}
#===============================================================================
# Write initial data summary in html outfile
#===============================================================================
    cat("<html><head></head><body>\n", file = htmloutfile);
    
    cat("<h1><u>QuanTP: Association between abundance ratios of transcript and protein</u></h1><hr/>\n",
    "<font><h3>Input data summary</h3></font>\n",
    "<ul>\n",
    "<li>Abbreviations used: PE (Proteome data) and TE (Transcriptome data)","</li><br>\n",
    "<li>Input Proteome data dimension (Row Column): ", dim(PE_df)[1]," x ", dim(PE_df)[2],"</li>\n",
    "<li>Input Transcriptome data dimension (Row Column): ", dim(TE_df)[1]," x ", dim(TE_df)[2],"</li></ul><hr/>\n",
    file = htmloutfile, append = TRUE);
    
    cat("<h3 id=table_of_content>Table of Contents:</h3>\n",
    "<ul>\n",
    "<li><a href=#sample_dist>Sample distribution</a></li>\n",
    "<li><a href=#corr_data>Correlation</a></li>\n",
    "<li><a href=#regression_data>Regression analysis</a></li>\n",
    "<li><a href=#inf_obs>Influential observations</a></li>\n",

PE_nacount = sum(is.na(PE_df));

TE_df[is.na(TE_df)] = 0;
PE_df[is.na(PE_df)] = 0;


#===============================================================================
# Decide based on analysis mode
#===============================================================================
if(mode=="logfold")
{
  cat('<h2 id="sample_dist"><font color=#ff0000>SAMPLE DISTRIBUTION</font></h2>\n',
  file = htmloutfile, append = TRUE);
  
  # TE Boxplot
  outplot = paste(outdir,"/Box_TE.png",sep="",collape="");
  cat('<table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; ">\n',
  '<tr bgcolor="#7a0019"><th><font color=#ffcc33>Boxplot: Transcriptome data</font></th><th><font color=#ffcc33>Boxplot: Proteome data</font></th></tr>\n',
  "<tr><td align=center>", '<img src="Box_TE.png" width=500 height=500></td>\n', file = htmloutfile, append = TRUE);
  multisample_boxplot(TE_df, sampleinfo_df, outplot, "Yes", "Samples", "Transcript Abundance data");
  
  # PE Boxplot
  outplot = paste(outdir,"/Box_PE.png",sep="",collape="");
  cat("<td align=center>", '<img src="Box_PE.png" width=500 height=500></td></tr></table>\n', file = htmloutfile, append = TRUE);
  multisample_boxplot(PE_df, sampleinfo_df, outplot, "Yes", "Samples", "Protein Abundance data");
  
  cat('<hr/><h2 id="corr_data"><font color=#ff0000>CORRELATION</font></h2>\n',
  file = htmloutfile, append = TRUE);
  
  # TE PE scatter
  outplot = paste(outdir,"/TE_PE_scatter.png",sep="",collape="");
  cat('<table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Scatter plot between Proteome and Transcriptome Abundance</font></th></tr>\n', file = htmloutfile, append = TRUE);
  cat("<tr><td align=center>", '<img src="TE_PE_scatter.png" width=800 height=800></td></tr>\n', file = htmloutfile, append = TRUE);
  PE_TE_data = data.frame(PE_df, TE_df);
  colnames(PE_TE_data) = c("PE_ID","PE_abundance","TE_ID","TE_abundance");
  singlesample_scatter(PE_TE_data, outplot);  
  
  # TE PE Cor
  cat("<tr><td align=center>", file = htmloutfile, append = TRUE);
  singlesample_cor(PE_TE_data, htmloutfile, append=TRUE);
  cat('<font color="red">*Note that <u>correlation</u> is <u>sensitive to outliers</u> in the data. So it is important to analyze outliers/influential observations in the data.<br> Below we use <u>Cook\'s distance based approach</u> to identify such influential observations.</font>\n',
    file = htmloutfile, append = TRUE);
  cat('</td></table>',
    file = htmloutfile, append = TRUE);
  
  cat('<hr/><h2 id="regression_data"><font color=#ff0000>REGRESSION ANALYSIS</font></h2>\n',
  file = htmloutfile, append = TRUE);
  
  # TE PE Regression
  singlesample_regression(PE_TE_data,htmloutfile, append=TRUE);
  
  cat('<hr/><h2 id="cluster_data"><font color=#ff0000>CLUSTER ANALYSIS</font></h2>\n',
  file = htmloutfile, append = TRUE);
  
  # TE PE Heatmap
  singlesample_heatmap(PE_TE_data, htmloutfile, hm_nclust);
  
  
  # TE PE Clustering (kmeans)
  singlesample_kmeans(PE_TE_data, htmloutfile, nclust=as.numeric(numCluster))
  
}else{
  if(mode=="multiple")
  {
    cat('<h2 id="sample_dist"><font color=#ff0000>SAMPLE DISTRIBUTION</font></h2>\n',
    file = htmloutfile, append = TRUE);
    
    # TE Boxplot
    outplot = paste(outdir,"/Box_TE_all_rep.png",sep="",collape="");
    cat('<table  border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; ">\n',
    '<tr bgcolor="#7a0019"><th><font color=#ffcc33>Boxplot: Transcriptome data</font></th><th><font color=#ffcc33>Boxplot: Proteome data</font></th></tr>\n',
    "<tr><td align=center>", '<img src="Box_TE_all_rep.png" width=500 height=500></td>\n', file = htmloutfile, append = TRUE);
    temp_df_te_data = data.frame(TE_df[,1], log(TE_df[,2:length(TE_df)]));
    colnames(temp_df_te_data) = colnames(TE_df);
    multisample_boxplot(temp_df_te_data, sampleinfo_df, outplot, "Yes", "Samples", "Transcript Abundance (log)");
    
    # PE Boxplot
    outplot = paste(outdir,"/Box_PE_all_rep.png",sep="",collape="");
    cat("<td align=center>", '<img src="Box_PE_all_rep.png" width=500 height=500></td></tr></table>\n', file = htmloutfile, append = TRUE);
    temp_df_pe_data = data.frame(PE_df[,1], log(PE_df[,2:length(PE_df)]));
    colnames(temp_df_pe_data) = colnames(PE_df);
    multisample_boxplot(temp_df_pe_data, sampleinfo_df, outplot, "Yes", "Samples", "Protein Abundance (log)");
    
    # Calc TE PCA
    outplot = paste(outdir,"/PCA_TE_all_rep.png",sep="",collape="");
    multisample_PCA(TE_df, sampleinfo_df, outplot);

    # Calc PE PCA
    outplot = paste(outdir,"/PCA_PE_all_rep.png",sep="",collape="");
    multisample_PCA(PE_df, sampleinfo_df, outplot);
    
    
    # Replicate mode
    templist = mergeReplicates(TE_df,PE_df, sampleinfo_df, method);
    TE_df = templist$TE_df_merged;
    PE_df = templist$PE_df_merged;
    sampleinfo_df = templist$sampleinfo_df_merged;
    rownames(sampleinfo_df) = sampleinfo_df[,1];
    
    # TE Boxplot
    outplot = paste(outdir,"/Box_TE_rep.png",sep="",collape="");
    cat('<br><font color="#ff0000"><h3>Sample wise distribution (Box plot) after using ',method,' on replicates </h3></font><table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Boxplot: Transcriptome data</font></th><th><font color=#ffcc33>Boxplot: Proteome data</font></th></tr>\n',
    "<tr><td align=center>", '<img src="Box_TE_rep.png" width=500 height=500></td>\n', file = htmloutfile, append = TRUE);
    temp_df_te_data = data.frame(TE_df[,1], log(TE_df[,2:length(TE_df)]));
    colnames(temp_df_te_data) = colnames(TE_df);
    multisample_boxplot(temp_df_te_data, sampleinfo_df, outplot, "No", "Sample Groups", "Mean Transcript Abundance (log)");

    # PE Boxplot
    outplot = paste(outdir,"/Box_PE_rep.png",sep="",collape="");
    cat("<td align=center>", '<img src="Box_PE_rep.png" width=500 height=500></td></tr></table>\n', file = htmloutfile, append = TRUE);
    temp_df_pe_data = data.frame(PE_df[,1], log(PE_df[,2:length(PE_df)]));
    colnames(temp_df_pe_data) = colnames(PE_df);
    multisample_boxplot(temp_df_pe_data, sampleinfo_df, outplot, "No", "Sample Groups", "Mean Protein Abundance (log)");

    #===============================================================================
    # Calculating log fold change and running the "single" code part 
    #===============================================================================

    TE_df = data.frame("Genes"=TE_df[,1], "LogFold"=apply(TE_df[,c(which(colnames(TE_df)==condition_g_name),which(colnames(TE_df)==control_g_name))],1,function(x) log(x[1]/x[2],base=2)));
    PE_df = data.frame("Genes"=PE_df[,1], "LogFold"=apply(PE_df[,c(which(colnames(PE_df)==condition_g_name),which(colnames(PE_df)==control_g_name))],1,function(x) log(x[1]/x[2],base=2)));
  
      #===============================================================================
      # Treat missing values
      #===============================================================================
  
      TE_df[is.infinite(TE_df[,2]),2] = NA;
      PE_df[is.infinite(PE_df[,2]),2] = NA;
      TE_df[is.na(TE_df)] = 0;
      PE_df[is.na(PE_df)] = 0;

      sampleinfo_df = data.frame("Sample"= c("LogFold"), "Group"=c("Fold_Change"))
      #===============================================================================
      # Find common samples
      #===============================================================================
  
      common_samples = intersect(sampleinfo_df[,1], colnames(TE_df)[-1]) %>% intersect(., colnames(PE_df)[-1]);
      TE_df =  select(TE_df, 1, common_samples);
      PE_df =  select(PE_df, 1, common_samples);
      sampleinfo_df = filter(sampleinfo_df, Sample %in% common_samples);
      rownames(sampleinfo_df) = sampleinfo_df[,1];
  
    # TE Boxplot
    outplot = paste(outdir,"/Box_TE.png",sep="",collape="");
    cat('<br><font color="#ff0000"><h3>Distribution (Box plot) of log fold change </h3></font>', file = htmloutfile, append = TRUE);
    cat('<table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Boxplot: Transcriptome data</font></th><th><font color=#ffcc33>Boxplot: Proteome data</font></th></tr>\n',
    "<tr><td align=center>", '<img src="Box_TE.png" width=500 height=500></td>\n', file = htmloutfile, append = TRUE);
    multisample_boxplot(TE_df, sampleinfo_df, outplot, "Yes", "Sample (log2(case/control))", "Transcript Abundance fold-change (log2)");
    
    # PE Boxplot
    outplot = paste(outdir,"/Box_PE.png",sep="",collape="");
    cat("<td align=center>", '<img src="Box_PE.png" width=500 height=500></td></tr></table>\n', file = htmloutfile, append = TRUE);
    multisample_boxplot(PE_df, sampleinfo_df, outplot, "Yes", "Sample (log2(case/control))", "Protein Abundance fold-change(log2)");
    
    
    # Log Fold Data
    perform_Test_Volcano(TE_df_orig,PE_df_orig,TE_df, PE_df,sampleinfo_df_orig,method,correction_method,volc_with)
    
    
    
    # Print PCA
    
    cat('<br><br><table  border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>PCA plot: Transcriptome data</font></th><th><font color=#ffcc33>PCA plot: Proteome data</font></th></tr>\n',
    "<tr><td align=center>", '<img src="PCA_TE_all_rep.png" width=500 height=500></td>\n',
    "<td align=center>", '<img src="PCA_PE_all_rep.png" width=500 height=500></td></tr></table>\n', 
      file = htmloutfile, append = TRUE);
    
    
    
    cat('<hr/><h2 id="corr_data"><font color=#ff0000>CORRELATION</font></h2>\n',
    file = htmloutfile, append = TRUE);
    
    # TE PE scatter
    outplot = paste(outdir,"/TE_PE_scatter.png",sep="",collape="");
    cat('<br><table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Scatter plot between Proteome and Transcriptome Abundance</font></th></tr>\n', file = htmloutfile, append = TRUE);
    cat("<tr><td align=center>", '<img src="TE_PE_scatter.png" width=800 height=800></td>\n', file = htmloutfile, append = TRUE);
    PE_TE_data = data.frame(PE_df, TE_df);
    colnames(PE_TE_data) = c("PE_ID","PE_abundance","TE_ID","TE_abundance");
    singlesample_scatter(PE_TE_data, outplot);  

    # TE PE Cor
    cat("<tr><td align=center>\n", file = htmloutfile, append = TRUE);
    singlesample_cor(PE_TE_data, htmloutfile, append=TRUE);
    cat('<font color="red">*Note that <u>correlation</u> is <u>sensitive to outliers</u> in the data. So it is important to analyze outliers/influential observations in the data.<br> Below we use <u>Cook\'s distance based approach</u> to identify such influential observations.</font>\n',
      file = htmloutfile, append = TRUE);
    cat('</td></table>',
    file = htmloutfile, append = TRUE);
    
    cat('<hr/><h2 id="regression_data"><font color=#ff0000>REGRESSION ANALYSIS</font></h2>\n',
    file = htmloutfile, append = TRUE);
    
    # TE PE Regression
    singlesample_regression(PE_TE_data,htmloutfile, append=TRUE);
    
    cat('<hr/><h2 id="cluster_data"><font color=#ff0000>CLUSTER ANALYSIS</font></h2>\n',
    file = htmloutfile, append = TRUE);
    
    #TE PE Heatmap
    singlesample_heatmap(PE_TE_data, htmloutfile, hm_nclust);
    
    #TE PE Clustering (kmeans)
    singlesample_kmeans(PE_TE_data, htmloutfile, nclust=as.numeric(numCluster))
    
  }
}
cat("<h3>Go To:</h3>\n",
    "<ul>\n",
    "<li><a href=#sample_dist>Sample distribution</a></li>\n",

    "<li><a href=#inf_obs>Influential observations</a></li>\n",
    "<li><a href=#cluster_data>Cluster analysis</a></li></ul>\n",
    "<br><a href=#>TOP</a>",
    file = htmloutfile, append = TRUE);
cat("</body></html>\n", file = htmloutfile, append = TRUE);

1:dec87511835e

  tempdf[is.na(tempdf)] = 0;
  tempdf$Group = tempgrp;
  png(outfile, width = 6, height = 6, units = 'in', res=300);
  # bitmap(outfile, "png16m");
  g = autoplot(prcomp(select(tempdf, -Group)), data = tempdf, colour = 'Group', size=3);
  saveWidget(ggplotly(g), file.path(gsub("\\.png", "\\.html", outplot)))
  plot(g);
  dev.off();
}

#===============================================================================

  rownames(PE_TE_data) = PE_TE_data$PE_ID;
  regmodel = lm(PE_abundance~TE_abundance, data=PE_TE_data);
  regmodel_summary = summary(regmodel);
  
  cat("<font><h3>Linear Regression model fit between Proteome and Transcriptome data</h3></font>\n",
      "<p>Assuming a linear relationship between Proteome and Transcriptome data, we here fit a linear regression model.</p>\n",
      '<table  border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Parameter</font></th><th><font color=#ffcc33>Value</font></th></tr>\n',
      file = htmloutfile, append = TRUE);
  
  cat("<tr><td>Formula</td><td>","PE_abundance~TE_abundance","</td></tr>\n",
      "<tr><td colspan='2' align='center'> <b>Coefficients</b></td>","</tr>\n",
      "<tr><td>",names(regmodel$coefficients[1]),"</td><td>",regmodel$coefficients[1]," (Pvalue:", regmodel_summary$coefficients[1,4],")","</td></tr>\n",
      "<tr><td>",names(regmodel$coefficients[2]),"</td><td>",regmodel$coefficients[2]," (Pvalue:", regmodel_summary$coefficients[2,4],")","</td></tr>\n",
      "<tr><td colspan='2' align='center'> <b>Model parameters</b></td>","</tr>\n",
      "<tr><td>Residual standard error</td><td>",regmodel_summary$sigma," (",regmodel_summary$df[2]," degree of freedom)</td></tr>\n",
      "<tr><td>F-statistic</td><td>",regmodel_summary$fstatistic[1]," ( on ",regmodel_summary$fstatistic[2]," and  ",regmodel_summary$fstatistic[3]," degree of freedom)</td></tr>\n",
      "<tr><td>R-squared</td><td>",regmodel_summary$r.squared,"</td></tr>\n",
      "<tr><td>Adjusted R-squared</td><td>",regmodel_summary$adj.r.squared,"</td></tr>\n",
      file = htmloutfile, append = TRUE);
  
  cat("</table>\n", file = htmloutfile, append = TRUE);
  
  cat(
    "<font color='#ff0000'><h3>Regression and diagnostics plots</h3></font>\n",

  # bitmap(outplot, "png16m");
  par(mfrow=c(1,1));
  plot(regmodel, 1, cex.lab=1.5);
  dev.off();
  
  suppressWarnings(g <- autoplot(regmodel, label = FALSE)[[1]] +
                     geom_point(aes(text=sprintf("Residual: %.2f<br>Fitted value: %.2f<br>Gene: %s", .fitted, .resid, PE_TE_data$PE_ID)),
                                shape = 1, size = .1, stroke = .2) +
                     theme_light())
  saveWidget(ggplotly(g, tooltip= c("text")), file.path(gsub("\\.png", "\\.html", outplot)))
  
  outplot = paste(outdir,"/PE_TE_lm_2.png",sep="",collapse="");
  png(outplot,width = 10, height = 10, units = 'in', res=300);
  # bitmap(outplot, "png16m");
  par(mfrow=c(1,1));
  g <- plot(regmodel, 2, cex.lab=1.5);
  ggplotly(g)
  dev.off();
  
  suppressWarnings(g <- autoplot(regmodel, label = FALSE)[[2]] +
                     geom_point(aes(text=sprintf("Standarized residual: %.2f<br>Theoretical quantile: %.2f<br>Gene: %s", .qqx, .qqy, PE_TE_data$PE_ID)),
                                shape = 1, size = .1) +
                     theme_light())
  saveWidget(ggplotly(g, tooltip = "text"), file.path(gsub("\\.png", "\\.html", outplot)))
  
  
  outplot = paste(outdir,"/PE_TE_lm_5.png",sep="",collapse="");
  png(outplot, width = 10, height = 10, units = 'in',res=300);
  # bitmap(outplot, "png16m");
  par(mfrow=c(1,1));
  plot(regmodel, 5, cex.lab=1.5);
  dev.off();
  
  cd_cont_pos <- function(leverage, level, model) {sqrt(level*length(coef(model))*(1-leverage)/leverage)}
  cd_cont_neg <- function(leverage, level, model) {-cd_cont_pos(leverage, level, model)}
  
  suppressWarnings(g <- autoplot(regmodel, label = FALSE)[[4]] +
                     aes(label = PE_TE_data$PE_ID) + 
                     geom_point(aes(text=sprintf("Leverage: %.2f<br>Standardized residual: %.2f<br>Gene: %s", .hat, .stdresid, PE_TE_data$PE_ID))) +
                     theme_light())
  saveWidget(ggplotly(g, tooltip = "text"), file.path(gsub("\\.png", "\\.html", outplot)))
  
  cat('<table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; ">', file = htmloutfile, append = TRUE);
  
  cat(
    '<tr bgcolor="#7a0019"><th>', "<font color='#ffcc33'><h4>1) <u>Residuals vs Fitted plot</h4></font></u></th>\n",
    '<th><font color=#ffcc33><h4>2) <u>Normal Q-Q plot of residuals</h4></font></u></th></tr>\n',
    file = htmloutfile, append = TRUE);
  
  cat(
    '<tr><td align=center><img src="PE_TE_lm_1.png" width=600 height=600>',
    gsub("width:500px;height:500px", "width:600px;height:600px", extractWidgetCode(paste(outdir,"/PE_TE_lm_1.png",sep="",collapse=""))$widget_div),
    '</td><td align=center><img src="PE_TE_lm_2.png" width=600 height=600>',
    gsub("width:500px;height:500px", "width:600px;height:600px", extractWidgetCode(paste(outdir,"/PE_TE_lm_2.png",sep="",collapse=""))$widget_div),
    '</td></tr>\n', file = htmloutfile, append = TRUE);
  
  cat(
    '<tr><td align=center>This plot checks for linear relationship assumptions.<br>If a horizontal line is observed without any distinct patterns, it indicates a linear relationship.</td>\n',
    '<td align=center>This plot checks whether residuals are normally distributed or not.<br>It is good if the residuals points follow the straight dashed line i.e., do not deviate much from dashed line.</td></tr></table>\n',
    file = htmloutfile, append = TRUE);
  
  
  #@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
  # Residuals data
  #@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
  res_all = regmodel$residuals;
  res_mean = mean(res_all);
  res_sd = sd(res_all);
  res_diff = (res_all-res_mean);
  res_zscore = res_diff/res_sd;
  # res_outliers = res_all[which((res_zscore > 2)|(res_zscore < -2))]
  
  
  tempind = which((res_zscore > 2)|(res_zscore < -2));
  res_PE_TE_data_no_outlier = PE_TE_data[-tempind,];
  res_PE_TE_data_no_outlier$residuals = res_all[-tempind];
  res_PE_TE_data_outlier = PE_TE_data[tempind,];
  res_PE_TE_data_outlier$residuals = res_all[tempind];
  
  # Save the complete table for download (influential_observations)
  temp_outlier_data = data.frame(res_PE_TE_data_outlier$PE_ID, res_PE_TE_data_outlier$TE_abundance, res_PE_TE_data_outlier$PE_abundance, res_PE_TE_data_outlier$residuals)
  colnames(temp_outlier_data) = c("Gene", "Transcript abundance", "Protein abundance", "Residual value")
  outdatafile = paste(outdir,"/PE_TE_outliers_residuals.txt", sep="", collapse="");
  write.table(temp_outlier_data, file=outdatafile, row.names=F, sep="\t", quote=F);
  
  
  # Save the complete table for download (non influential_observations)
  temp_all_data = data.frame(PE_TE_data$PE_ID, PE_TE_data$TE_abundance, PE_TE_data$PE_abundance, res_all)
  colnames(temp_all_data) = c("Gene", "Transcript abundance", "Protein abundance", "Residual value")
  outdatafile = paste(outdir,"/PE_TE_abundance_residuals.txt", sep="", collapse="");
  write.table(temp_all_data, file=outdatafile, row.names=F, sep="\t", quote=F);
  
  
  cat('<br><h2 id="inf_obs"><font color=#ff0000>Outliers based on the residuals from regression analysis</font></h2>\n',
      file = htmloutfile, append = TRUE);
  cat('<table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; ">\n',
      '<tr bgcolor="#7a0019"><th colspan=2><font color=#ffcc33>Residuals from Regression</font></th></tr>\n',
      '<tr bgcolor="#7a0019"><th><font color=#ffcc33>Parameter</font></th><th><font color=#ffcc33>Value</font></th></tr>\n',
      file = htmloutfile, append = TRUE);
  
  cat("<tr><td>Mean Residual value</td><td>",res_mean,"</td></tr>\n",
      "<tr><td>Standard deviation (Residuals)</td><td>",res_sd,"</td></tr>\n",
      '<tr><td>Total outliers (Residual value > 2 standard deviation from the mean)</td><td>',length(tempind),' <font size=4>(<b><a href="PE_TE_outliers_residuals.txt" target="_blank">Download these ',length(tempind),' data points with high residual values here</a></b>)</font></td>\n',
      '<tr><td colspan=2 align=center>',
      '<font size=4>(<b><a href="PE_TE_abundance_residuals.txt" target="_blank">Download the complete residuals data here</a></b>)</font>',
      "</td></tr>\n</table><br><br>\n",
      file = htmloutfile, append = TRUE);
  
  #@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
  
  
  cat('<br><br><table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; ">', file = htmloutfile, append = TRUE);
  
  cat(
    '<tr bgcolor="#7a0019"><th><font color=#ffcc33><h4>3) <u>Residuals vs Leverage plot</h4></font></u></th></tr>\n',
    file = htmloutfile, append = TRUE);
  
  cat(
    '<tr><td align=center><img src="PE_TE_lm_5.png" width=600 height=600>', 
    gsub("width:500px;height:500px", "width:600px;height:600px", extractWidgetCode(paste(outdir,"/PE_TE_lm_5.png",sep="",collapse=""))$widget_div)
    , '</td></tr>\n',
    file = htmloutfile, append = TRUE);
  
  cat(
    '<tr><td align=center>This plot is useful to identify any influential cases, that is outliers or extreme values.<br>They might influence the regression results upon inclusion or exclusion from the analysis.</td></tr></table><br>\n',
    file = htmloutfile, append = TRUE);

  
  #^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
  # Cook's Distance
  #^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
  cat('<hr/><h2 id="inf_obs"><font color=#ff0000>INFLUENTIAL OBSERVATIONS</font></h2>\n',
      file = htmloutfile, append = TRUE);
  cat(
    '<p><b>Cook\'s distance</b> computes the influence of each data point/observation on the predicted outcome. i.e. this measures how much the observation is influencing the fitted values.<br>In general use, those observations that have a <b>Cook\'s distance > than ', cookdist_upper_cutoff,' times the mean</b> may be classified as <b>influential.</b></p>\n',
    file = htmloutfile, append = TRUE);
  
  cooksd <- cooks.distance(regmodel);

  points(sel_nonoutlier, cooksd[sel_nonoutlier],pch="*", cex=2, cex.lab=1.5, col="black")
  abline(h = as.numeric(cookdist_upper_cutoff)*mean(cooksd, na.rm=T), col="red")  # add cutoff line
  #text(x=1:length(cooksd)+1, y=cooksd, labels=ifelse(cooksd>as.numeric(cookdist_upper_cutoff)*mean(cooksd, na.rm=T),names(cooksd),""), col="red", pos=2)  # add labels
  dev.off();
  
  cooksd_df <- data.frame(cooksd)
  cooksd_df$genes <- row.names(cooksd_df)
  cooksd_df$index <- 1:nrow(cooksd_df)
  cooksd_df$colors <- "black"
  cutoff <- as.numeric(cookdist_upper_cutoff)*mean(cooksd, na.rm=T)
  cooksd_df[cooksd_df$cooksd > cutoff,]$colors <- "red"
  
  g <- ggplot(cooksd_df, aes(x = index, y = cooksd, label = row.names(cooksd_df), color=as.factor(colors), 
                             text=sprintf("Gene: %s<br>Cook's Distance: %.3f", row.names(cooksd_df), cooksd))) +
    ggtitle("Influential Obs. by Cook's distance") + xlab("Observations") + ylab("Cook's Distance") + 
    #xlim(0, 3000) + ylim(0, .15) + 
    scale_shape_discrete(solid=F) +
    geom_point(size = 2, shape = 8)  + 
    geom_hline(yintercept = cutoff, 
               linetype = "dashed", color = "red") + 
    scale_color_manual(values = c("black" = "black", "red" = "red")) + 
    theme_light() + theme(legend.position="none")
  saveWidget(ggplotly(g, tooltip= "text"), file.path(gsub("\\.png", "\\.html", outplot)))
  
  cat(
    '<img src="PE_TE_lm_cooksd.png" width=800 height=800>',
    gsub("width:500px;height:500px", "width:800px;height:800px", extractWidgetCode(outplot)$widget_div),
    '<br>In the above plot, observations above red line (',cookdist_upper_cutoff,' * mean Cook\'s distance) are influential. Genes that are outliers could be important. These observations influences the correlation values and regression coefficients<br><br>',
    file = htmloutfile, append = TRUE);    
  
  tempind = which(cooksd>as.numeric(cookdist_upper_cutoff)*mean(cooksd, na.rm=T));
  PE_TE_data_no_outlier = PE_TE_data[-tempind,];
  PE_TE_data_no_outlier$cooksd = cooksd[-tempind];
  PE_TE_data_outlier = PE_TE_data[tempind,];
  PE_TE_data_outlier$cooksd = cooksd[tempind];

  cat(
    '<table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Parameter</font></th><th><font color=#ffcc33>Value</font></th></tr>\n',
    file = htmloutfile, append = TRUE);
  
  # Save the complete table for download (influential_observations)
  temp_outlier_data = data.frame(PE_TE_data_outlier$PE_ID, PE_TE_data_outlier$TE_abundance, PE_TE_data_outlier$PE_abundance, PE_TE_data_outlier$cooksd)
  colnames(temp_outlier_data) = c("Gene", "Transcript abundance", "Protein abundance", "Cook's distance")
  outdatafile = paste(outdir,"/PE_TE_influential_observation.txt", sep="", collapse="");
  write.table(temp_outlier_data, file=outdatafile, row.names=F, sep="\t", quote=F);
  
  
  # Save the complete table for download (non influential_observations)
  temp_no_outlier_data = data.frame(PE_TE_data_no_outlier$PE_ID, PE_TE_data_no_outlier$TE_abundance, PE_TE_data_no_outlier$PE_abundance, PE_TE_data_no_outlier$cooksd)
  colnames(temp_no_outlier_data) = c("Gene", "Transcript abundance", "Protein abundance", "Cook's distance")
  outdatafile = paste(outdir,"/PE_TE_non_influential_observation.txt", sep="", collapse="");
  write.table(temp_no_outlier_data, file=outdatafile, row.names=F, sep="\t", quote=F);
  
  
  cat("<tr><td>Mean Cook\'s distance</td><td>",mean(cooksd, na.rm=T),"</td></tr>\n",
      "<tr><td>Total influential observations (Cook\'s distance > ",cookdist_upper_cutoff," * mean Cook\'s distance)</td><td>",length(tempind),"</td>\n",
      
      "<tr><td>Observations with Cook\'s distance < ",cookdist_upper_cutoff," * mean Cook\'s distance</td><td>",length(which(cooksd<as.numeric(cookdist_upper_cutoff)*mean(cooksd, na.rm=T))),"</td>\n",
      "</table><br><br>\n",
      file = htmloutfile, append = TRUE);
  
  
  #@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
  # Scatter plot after removal of influential points
  #@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
  outplot = paste(outdir,"/AbundancePlot_scatter_without_outliers.png",sep="",collapse="");
  min_lim = min(c(PE_TE_data$PE_abundance,PE_TE_data$TE_abundance));
  max_lim = max(c(PE_TE_data$PE_abundance,PE_TE_data$TE_abundance));
  png(outplot, width = 10, height = 10, units = 'in', res=300);
  # bitmap(outplot,"png16m");
  suppressWarnings(g <- ggplot(PE_TE_data_no_outlier, aes(x=TE_abundance, y=PE_abundance, label=PE_ID)) + geom_smooth() + 
                     xlab("Transcript abundance log fold-change") + ylab("Protein abundance log fold-change") + 
                     xlim(min_lim,max_lim) + ylim(min_lim,max_lim) +
                     geom_point(aes(text=sprintf("Gene: %s<br>Transcript Abundance (log fold-change): %.3f<br>Protein Abundance (log fold-change): %.3f",
                                                 PE_ID, TE_abundance, PE_abundance))))
  suppressMessages(plot(g))
  suppressMessages(saveWidget(ggplotly(g, tooltip="text"), file.path(gsub("\\.png", "\\.html", outplot))))
  dev.off();
  
  
  cat('<table  border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Scatterplot: Before removal</font></th><th><font color=#ffcc33>Scatterplot: After removal</font></th></tr>\n', file = htmloutfile, append = TRUE);
  # Before
  cat("<tr><td align=center><!--<font color='#ff0000'><h3>Scatter plot between Proteome and Transcriptome Abundance</h3></font>\n-->",
      '<img src="TE_PE_scatter.png" width=600 height=600>',
      gsub('id="html', 'id="secondhtml"',
           gsub("width:500px;height:500px", "width:600px;height:600px", extractWidgetCode(paste(outdir,"/TE_PE_scatter.png",sep="",collapse=""))$widget_div)),
      '</td>\n',
      file = htmloutfile, append = TRUE);
  
  # After
  cat("<td align=center>\n",
      '<img src="AbundancePlot_scatter_without_outliers.png" width=600 height=600>',
      gsub("width:500px;height:500px", "width:600px;height:600px", extractWidgetCode(outplot)$widget_div),
      
      '</td></tr>\n',
      file = htmloutfile, append = TRUE);
  #@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
  
  
  cor_result_pearson = cor.test(PE_TE_data_no_outlier[,"TE_abundance"], PE_TE_data_no_outlier[,"PE_abundance"], method = "pearson");
  cor_result_spearman = cor.test(PE_TE_data_no_outlier[,"TE_abundance"], PE_TE_data_no_outlier[,"PE_abundance"], method = "spearman");
  cor_result_kendall = cor.test(PE_TE_data_no_outlier[,"TE_abundance"], PE_TE_data_no_outlier[,"PE_abundance"], method = "kendall");
  

  singlesample_cor(PE_TE_data, htmloutfile, append=TRUE);
  cat('</td>\n', file = htmloutfile, append=TRUE);
  
  
  cat('<td><table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Parameter</font></th><th><font color=#ffcc33>Method 1</font></th><th><font color=#ffcc33>Method 2</font></th><th><font color=#ffcc33>Method 3</font></th></tr>\n',
      file = htmloutfile, append = TRUE);
  
  cat(
    "<tr><td>Correlation method</td><td>",cor_result_pearson$method,"</td><td>",cor_result_spearman$method,"</td><td>",cor_result_kendall$method,"</td></tr>\n",
    "<tr><td>Correlation coefficient</td><td>",cor_result_pearson$estimate,"</td><td>",cor_result_spearman$estimate,"</td><td>",cor_result_kendall$estimate,"</td></tr>\n",
    file = htmloutfile, append = TRUE)

  }else{
    tab_n_row = 10;
  }
  
  cat("<br><br><font size=5><b><a href='PE_TE_influential_observation.txt' target='_blank'>Download the complete list of influential observations</a></b></font>&nbsp;&nbsp;&nbsp;&nbsp;",
      "<font size=5><b><a href='PE_TE_non_influential_observation.txt' target='_blank'>Download the complete list (After removing influential points)</a></b></font><br>\n",
      '<br><font color="brown"><h4>Top ',as.character(tab_n_row),' Influential observations (Cook\'s distance > ',cookdist_upper_cutoff,' * mean Cook\'s distance)</h4></font>\n',
      file = htmloutfile, append = TRUE);
  
  cat('<table border=1 cellspacing=0 cellpadding=5> <tr bgcolor="#7a0019">\n', sep = "",file = htmloutfile, append = TRUE);
  cat("<th><font color=#ffcc33>Gene</font></th><th><font color=#ffcc33>Protein Log Fold-Change</font></th><th><font color=#ffcc33>Transcript Log Fold-Change</font></th><th><font color=#ffcc33>Cook's Distance</font></th></tr>\n",
      file = htmloutfile, append = TRUE);
  
  
  for(i in 1:tab_n_row)
  {
    cat(

      '<td>',format(PE_TE_data_outlier_sorted[i,2], scientific=F),'</td>\n',
      '<td>',PE_TE_data_outlier_sorted[i,4],'</td>\n',
      '<td>',format(PE_TE_data_outlier_sorted[i,5], scientific=F),'</td></tr>\n',
      file = htmloutfile, append = TRUE);
  }
  cat('</table><br><br>\n',file = htmloutfile, append = TRUE);
  
  
}



#===============================================================================
# Heatmap
#===============================================================================
singlesample_heatmap=function(PE_TE_data, htmloutfile, hm_nclust){
  cat('<br><table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Heatmap of PE and TE abundance values (Hierarchical clustering)</font></th><th><font color=#ffcc33>Number of clusters to extract: ',hm_nclust,'</font></th></tr>\n',
      file = htmloutfile, append = TRUE);
  
  hc=hclust(dist(as.matrix(PE_TE_data[,c("PE_abundance","TE_abundance")])))
  hm_cluster = cutree(hc,k=hm_nclust);
  
  outplot = paste(outdir,"/PE_TE_heatmap.png",sep="",collapse="");
  png(outplot, width = 10, height = 10, units = 'in', res=300);
  # bitmap(outplot, "png16m");
  par(mfrow=c(1,1));
  hmap = heatmap.2(as.matrix(PE_TE_data[,c("PE_abundance","TE_abundance")]),
                   trace="none", cexCol=1, col=greenred(100),Colv=F, 
                   labCol=c("Proteins","Transcripts"), scale="col", 
                   hclustfun = hclust, distfun = dist);
  
  dev.off();
  
  
  p <- d3heatmap(as.matrix(PE_TE_data[,c("PE_abundance","TE_abundance")]), scale = "col",
                 dendrogram = "row", colors = greenred(100),
                 hclustfun = hclust, distfun = dist,
                 show_grid = FALSE)
  saveWidget(p, file.path(gsub("\\.png", "\\.html", outplot)))
  
  cat('<tr><td align=center colspan="2">',
      '<img src="PE_TE_heatmap.png" width=800 height=800>',
      gsub("width:960px;height:500px", "width:800px;height:800px", extractWidgetCode(outplot)$widget_div),
      '</td></tr>\n',
      file = htmloutfile, append = TRUE);
  
  
  temp_PE_TE_data = data.frame(PE_TE_data$PE_ID, PE_TE_data$TE_abundance, PE_TE_data$PE_abundance, hm_cluster);
  colnames(temp_PE_TE_data) = c("Gene", "Transcript abundance", "Protein abundance", "Cluster (Hierarchical clustering)")
  tempoutfile = paste(outdir,"/PE_TE_hc_clusterpoints.txt",sep="",collapse="");
  write.table(temp_PE_TE_data, file=tempoutfile, row.names=F, quote=F, sep="\t", eol="\n")
  
  
  cat('<tr><td colspan="2" align=center><font size=5><a href="PE_TE_hc_clusterpoints.txt" target="_blank"><b>Download the hierarchical cluster list</b></a></font></td></tr></table>\n',
      file = htmloutfile, append = TRUE);
}


#===============================================================================
# K-means clustering

  # bitmap(outplot, "png16m");
  par(mfrow=c(1,1));
  scatter.smooth(PE_TE_data_kdata[,"TE_abundance"], PE_TE_data_kdata[,"PE_abundance"], xlab="Transcript Abundance", ylab="Protein Abundance", cex.lab=1.5);
  legend(1, 95, legend=c("Cluster 1", "Line 2"), col="red", lty=1:1, cex=0.8)
  legend(1, 95, legend="Cluster 2", col="green", lty=1:1, cex=0.8)
  
  ind=which(k1$cluster==1);
  points(PE_TE_data_kdata[ind,"TE_abundance"], PE_TE_data_kdata[ind,"PE_abundance"], col="red", pch=16);
  ind=which(k1$cluster==2);
  points(PE_TE_data_kdata[ind,"TE_abundance"], PE_TE_data_kdata[ind,"PE_abundance"], col="green", pch=16);

  points(PE_TE_data_kdata[ind,"TE_abundance"], PE_TE_data_kdata[ind,"PE_abundance"], col="yellow", pch=16);
  ind=which(k1$cluster==10);
  points(PE_TE_data_kdata[ind,"TE_abundance"], PE_TE_data_kdata[ind,"PE_abundance"], col="orange", pch=16);
  dev.off();
  
  # Interactive plot for k-means clustering
  g <- ggplot(PE_TE_data, aes(x = TE_abundance, y = PE_abundance, label = row.names(PE_TE_data),
                              text=sprintf("Gene: %s<br>Transcript Abundance: %.3f<br>Protein Abundance: %.3f",
                                           PE_ID, TE_abundance, PE_abundance),
                              color=as.factor(k1$cluster))) +
    xlab("Transcript Abundance") + ylab("Protein Abundance") + 
    scale_shape_discrete(solid=F) + geom_smooth(method = "loess", span = 2/3) +
    geom_point(size = 1, shape = 8) +
    theme_light() + theme(legend.position="none")
  saveWidget(ggplotly(g, tooltip=c("text")), file.path(gsub("\\.png", "\\.html", outplot)))
  
  cat('<br><br><table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>K-mean clustering</font></th><th><font color=#ffcc33>Number of clusters: ',nclust,'</font></th></tr>\n',
      file = htmloutfile, append = TRUE);
  
  tempind = order(k1$cluster);
  tempoutfile = paste(outdir,"/PE_TE_kmeans_clusterpoints.txt",sep="",collapse="");
  write.table(data.frame(PE_TE_data_kdata[tempind, ], Cluster=k1$cluster[tempind]), file=tempoutfile, row.names=F, quote=F, sep="\t", eol="\n")
  
  #paste(outdir,"/PE_TE_heatmap.png",sep="",collapse="");
  cat('<tr><td colspan="2" align=center><img src="PE_TE_kmeans.png" width=800 height=800>',
      gsub("width:500px;height:500px", "width:800px;height:800px", extractWidgetCode(outplot)$widget_div), '</td></tr>\n',
      file = htmloutfile, append = TRUE);
  cat('<tr><td colspan="2" align=center><font size=5><a href="PE_TE_kmeans_clusterpoints.txt" target="_blank"><b>Download the cluster list</b></a></font></td></tr></table><br><hr/>\n',
      file = htmloutfile, append = TRUE);
  
}

#===============================================================================
# scatter plot

{
  min_lim = min(c(PE_TE_data$PE_abundance,PE_TE_data$TE_abundance));
  max_lim = max(c(PE_TE_data$PE_abundance,PE_TE_data$TE_abundance));
  png(outfile, width = 10, height = 10, units = 'in', res=300);
  # bitmap(outfile, "png16m");
  suppressWarnings(g <- ggplot(PE_TE_data, aes(x=TE_abundance, y=PE_abundance, label=PE_ID)) + geom_smooth() + 
                     xlab("Transcript abundance log fold-change") + ylab("Protein abundance log fold-change") + 
                     xlim(min_lim,max_lim) + ylim(min_lim,max_lim) +
                     geom_point(aes(text=sprintf("Gene: %s<br>Transcript Abundance (log fold-change): %.3f<br>Protein Abundance (log fold-change): %.3f",
                                                 PE_ID, TE_abundance, PE_abundance)),
                                size = .5))
  suppressMessages(plot(g))
  suppressMessages(saveWidget(ggplotly(g, tooltip = "text"), file.path(gsub("\\.png", "\\.html", outfile))))
  dev.off();
}

#===============================================================================
# Correlation table

  tempdf = df[,-1, drop=FALSE];
  tempdf = t(tempdf) %>% as.data.frame();
  tempdf[is.na(tempdf)] = 0;
  tempdf$Sample = rownames(tempdf);
  tempdf1 = melt(tempdf, id.vars = "Sample");
  
  if("Gene" %in% colnames(df)){
    tempdf1$Name = df$Gene;
  } else if ("Protein" %in% colnames(df)){
    tempdf1$Name = df$Protein;
  } else if ("Genes" %in% colnames(df)){
    tempdf1$Name = df$Genes;
  }
  
  tempdf1$Group = sampleinfo_df[tempdf1$Sample,2];
  png(outplot, width = 6, height = 6, units = 'in', res=300);
  # bitmap(outplot, "png16m");
  if(fill_leg=="No"){
    tempdf1$Group = c("case", "control")
  }
  
  g = ggplot(tempdf1, aes(x=Sample, y=value, fill=Group)) + 
    geom_boxplot()+
    labs(x=user_xlab) + labs(y=user_ylab)
  saveWidget(ggplotly(g), file.path(gsub("\\.png", "\\.html", outfile)))
  plot(g);
  dev.off();
}

## A wrapper to saveWidget which compensates for arguable BUG in
## saveWidget which requires `file` to be in current working
## directory.
saveWidget <- function (widget,file,...) {
  wd<-getwd()
  on.exit(setwd(wd))
  outDir<-dirname(file)
  file<-basename(file)
  setwd(outDir);
  htmlwidgets::saveWidget(widget,file=file,selfcontained = FALSE)
}

#===============================================================================
# Mean or Median of Replicates
#===============================================================================

mergeReplicates = function(TE_df,PE_df, sampleinfo_df, method)
{
  grps = unique(sampleinfo_df[,2]);
  
  TE_df_merged <<- sapply(grps, function(x){
    tempsample = sampleinfo_df[which(sampleinfo_df$Group==x),1]
    if(length(tempsample)!=1){
      apply(TE_df[,tempsample],1,method);
    }else{
      return(TE_df[,tempsample]);
    }
  });
  TE_df_merged <<-   data.frame(as.character(TE_df[,1]), TE_df_merged);
  colnames(TE_df_merged) = c(colnames(TE_df)[1], grps);
  
  PE_df_merged <<- sapply(grps, function(x){
    tempsample = sampleinfo_df[which(sampleinfo_df$Group==x),1]
    if(length(tempsample)!=1){
      apply(PE_df[,tempsample],1,method);
    }else{
      return(PE_df[,tempsample]);
    }
  });
  
  PE_df_merged <<-   data.frame(as.character(PE_df[,1]), PE_df_merged);
  colnames(PE_df_merged) = c(colnames(PE_df)[1], grps);
  
  #sampleinfo_df_merged =  data.frame(Sample = grps, Group = grps, stringsAsFactors = F);
  sampleinfo_df_merged =  data.frame(Sample = grps, Group = "Group", stringsAsFactors = F);
  
  return(list(TE_df_merged = TE_df_merged, PE_df_merged = PE_df_merged, sampleinfo_df_merged = sampleinfo_df_merged));
}

#===============================================================================
# (T-Test or Wilcoxon ranksum test) and Volcano Plot
#===============================================================================

perform_Test_Volcano = function(TE_df_data,PE_df_data,TE_df_logfold, PE_df_logfold,sampleinfo_df, method, correction_method,volc_with)
{
  
  PE_colnames = colnames(PE_df_data);
  control_sample = sampleinfo_df[which(sampleinfo_df$Group=="control"),1];
  control_ind <<- sapply(control_sample, function(x){temp_ind = which(PE_colnames==x); as.numeric(temp_ind)});
  condition_sample = sampleinfo_df[which(sampleinfo_df$Group=="case"),1];
  condition_ind <<- sapply(condition_sample, function(x){temp_ind = which(PE_colnames==x); as.numeric(temp_ind)});
  
  if(method=="mean"){
    #PE_pval = apply(PE_df_data[2:length(colnames(PE_df_data))],1,function(x) t.test(x[condition_ind-1], x[control_ind-1])$p.value);
    PE_pval = apply(PE_df_data[2:length(colnames(PE_df_data))],1,function(x) {obj<-try(t.test(x[condition_ind-1], x[control_ind-1]),silent=TRUE); if(is(obj, "try-error")){return(NA)}else{return(obj$p.value)}})
  }else{
    if(method=="median"){
      PE_pval = apply(PE_df_data[2:length(colnames(PE_df_data))],1,function(x) {obj<-try(wilcox.test(x[condition_ind-1], x[control_ind-1]),silent=TRUE); if(is(obj, "try-error")){return(NA)}else{return(obj$p.value)}})
      # PE_pval = apply(PE_df_data[2:length(colnames(PE_df_data))],1,function(x) wilcox.test(x[condition_ind-1], x[control_ind-1])$p.value);
    }
  }
  PE_adj_pval = p.adjust(PE_pval, method = correction_method, n = length(PE_pval))
  
  
  TE_colnames = colnames(TE_df_data);
  control_sample = sampleinfo_df[which(sampleinfo_df$Group=="control"),1];
  control_ind <<- sapply(control_sample, function(x){temp_ind = which(TE_colnames==x); as.numeric(temp_ind)});
  condition_sample = sampleinfo_df[which(sampleinfo_df$Group=="case"),1];
  condition_ind <<- sapply(condition_sample, function(x){temp_ind = which(TE_colnames==x); as.numeric(temp_ind)});
  
  if(method=="mean"){
    # TE_pval = apply(TE_df_data[2:length(colnames(TE_df_data))],1,function(x) t.test(x[condition_ind-1], x[control_ind-1])$p.value);
    TE_pval = apply(TE_df_data[2:length(colnames(TE_df_data))],1,function(x) {obj<-try(t.test(x[condition_ind-1], x[control_ind-1]),silent=TRUE); if(is(obj, "try-error")){return(NA)}else{return(obj$p.value)}})
  }else{
    if(method=="median"){
      TE_pval = apply(TE_df_data[2:length(colnames(TE_df_data))],1,function(x) {obj<-try(wilcox.test(x[condition_ind-1], x[control_ind-1]),silent=TRUE); if(is(obj, "try-error")){return(NA)}else{return(obj$p.value)}})
      # TE_pval = apply(TE_df_data[2:length(colnames(TE_df_data))],1,function(x) wilcox.test(x[condition_ind-1], x[control_ind-1])$p.value);
    }
  }
  TE_adj_pval = p.adjust(TE_pval, method = correction_method, n = length(TE_pval))
  
  
  PE_TE_logfold_pval = data.frame(TE_df_logfold$Gene, TE_df_logfold$LogFold, TE_pval, TE_adj_pval, PE_df_logfold$LogFold, PE_pval, PE_adj_pval);
  colnames(PE_TE_logfold_pval) = c("Gene", "Transcript log fold-change", "p-value (transcript)", "adj p-value (transcript)", "Protein log fold-change", "p-value (protein)", "adj p-value (protein)");
  outdatafile = paste(outdir,"/PE_TE_logfold_pval.txt", sep="", collapse="");
  write.table(PE_TE_logfold_pval, file=outdatafile, row.names=F, sep="\t", quote=F);
  cat("<br><br><font size=5><b><a href='PE_TE_logfold_pval.txt' target='_blank'>Download the complete fold change data here</a></b></font><br>\n",
      file = htmloutfile, append = TRUE);
  
  if(length(condition_ind)!=1)
  {
    # Volcano Plot
    
    if(volc_with=="adj_pval")
    {
      PE_pval = PE_adj_pval
      TE_pval = TE_adj_pval
      volc_ylab = "-log10 Adjusted p-value";
    }else{
      if(volc_with=="pval")
      {
        volc_ylab = "-log10 p-value";
      }
    }
    outplot_PE = paste(outdir,"/PE_volcano.png",sep="",collapse="");
    png(outplot_PE, width = 10, height = 10, units = 'in', res=300);
    # bitmap(outplot, "png16m");
    par(mfrow=c(1,1));
    
    plot(PE_df_logfold$LogFold, -log10(PE_pval),
         xlab="log2 fold change", ylab=volc_ylab,
         type="n")
    sel <- which((PE_df_logfold$LogFold<=log(2,base=2))&(PE_df_logfold$LogFold>=log(0.5, base=2))) # or whatever you want to use
    points(PE_df_logfold[sel,"LogFold"], -log10(PE_pval[sel]),col="black")
    PE_df_logfold$color <- "black"
    #sel <- which((PE_df_logfold$LogFold>log(2,base=2))&(PE_df_logfold$LogFold<log(0.5,base=2))) # or whatever you want to use
    sel <- which((PE_df_logfold$LogFold>log(2,base=2))|(PE_df_logfold$LogFold<log(0.5, base=2)))
    sel1 <- which(PE_pval<=0.05)
    sel=intersect(sel,sel1)
    points(PE_df_logfold[sel,"LogFold"], -log10(PE_pval[sel]),col="red")
    PE_df_logfold[sel,]$color <- "red"
    sel <- which((PE_df_logfold$LogFold>log(2,base=2))|(PE_df_logfold$LogFold<log(0.5, base=2)))
    sel1 <- which(PE_pval>0.05)
    sel=intersect(sel,sel1)
    points(PE_df_logfold[sel,"LogFold"], -log10(PE_pval[sel]),col="blue")
    PE_df_logfold[sel,]$color <- "blue"
    abline(h = -log(0.05,base=10), col="red", lty=2)
    abline(v = log(2,base=2), col="red", lty=2)
    abline(v = log(0.5,base=2), col="red", lty=2)
    dev.off();
    
    g <- ggplot(PE_df_logfold, aes(x = LogFold, -log10(PE_pval), color = as.factor(color),
                                   text=sprintf("Gene: %s<br>Log2 Fold-Change: %.3f<br>-log10 p-value: %.3f<br>p-value: %.3f",
                                                Genes, LogFold, -log10(PE_pval), PE_pval))) +
      xlab("log2 fold change") + ylab("-log10 p-value") + 
      geom_point(shape=1, size = 1.5, stroke = .2) +
      scale_color_manual(values = c("black" = "black", "red" = "red", "blue" = "blue")) + 
      geom_hline(yintercept = -log(0.05,base=10), linetype="dashed", color="red") +
      geom_vline(xintercept = log(2,base=2), linetype="dashed", color="red") +
      geom_vline(xintercept = log(0.5,base=2), linetype="dashed", color="red") +
      theme_light() + theme(legend.position="none")
    saveWidget(ggplotly(g, tooltip="text"), file.path(gsub("\\.png", "\\.html", outplot_PE)))
    
    outplot_TE = paste(outdir,"/TE_volcano.png",sep="",collapse="");
    png(outplot_TE, width = 10, height = 10, units = 'in', res=300);
    # bitmap(outplot, "png16m");
    par(mfrow=c(1,1));
    
    plot(TE_df_logfold$LogFold, -log10(TE_pval),
         xlab="log2 fold change", ylab=volc_ylab,
         type="n")
    
    sel <- which((TE_df_logfold$LogFold<=log(2,base=2))&(TE_df_logfold$LogFold>=log(0.5, base=2))) # or whatever you want to use
    points(TE_df_logfold[sel,"LogFold"], -log10(TE_pval[sel]),col="black")
    TE_df_logfold$color <- "black"
    #sel <- which((TE_df_logfold$LogFold>log(2,base=2))&(TE_df_logfold$LogFold<log(0.5,base=2))) # or whatever you want to use
    sel <- which((TE_df_logfold$LogFold>log(2,base=2))|(TE_df_logfold$LogFold<log(0.5, base=2)))
    sel1 <- which(TE_pval<=0.05)
    sel=intersect(sel,sel1)
    points(TE_df_logfold[sel,"LogFold"], -log10(TE_pval[sel]),col="red")
    TE_df_logfold[sel,]$color <- "red"
    sel <- which((TE_df_logfold$LogFold>log(2,base=2))|(TE_df_logfold$LogFold<log(0.5, base=2)))
    sel1 <- which(TE_pval>0.05)
    sel=intersect(sel,sel1)
    points(TE_df_logfold[sel,"LogFold"], -log10(TE_pval[sel]),col="blue")
    TE_df_logfold[sel,]$color <- "blue"
    abline(h = -log(0.05,base=10), col="red", lty=2)
    abline(v = log(2,base=2), col="red", lty=2)
    abline(v = log(0.5,base=2), col="red", lty=2)
    dev.off();
    
    g <- ggplot(TE_df_logfold, aes(x = LogFold, -log10(TE_pval), color = as.factor(color),
                                   text=sprintf("Gene: %s<br>Log2 Fold-Change: %.3f<br>-log10 p-value: %.3f<br>p-value: %.3f",
                                                Genes, LogFold, -log10(TE_pval), TE_pval))) +
      xlab("log2 fold change") + ylab("-log10 p-value") + 
      geom_point(shape=1, size = 1.5, stroke = .2) +
      scale_color_manual(values = c("black" = "black", "red" = "red", "blue" = "blue")) + 
      geom_hline(yintercept = -log(0.05,base=10), linetype="dashed", color="red") +
      geom_vline(xintercept = log(2,base=2), linetype="dashed", color="red") +
      geom_vline(xintercept = log(0.5,base=2), linetype="dashed", color="red") +
      theme_light() + theme(legend.position="none")
    saveWidget(ggplotly(g, tooltip="text"), file.path(gsub("\\.png", "\\.html", outplot_TE)))
    
    
    cat('<br><table  border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Transcript Fold-Change</font></th><th><font color=#ffcc33>Protein Fold-Change</font></th></tr>\n', file = htmloutfile, append = TRUE);
    cat("<tr><td align=center>", 
        '<img src="TE_volcano.png" width=600 height=600>',
        extractWidgetCode(outplot_TE)$widget_div,
        '</td>\n', file = htmloutfile, append = TRUE);
    cat("<td align=center>",
        '<img src="PE_volcano.png" width=600 height=600>',
        extractWidgetCode(outplot_PE)$widget_div,
        '</td></tr></table><br>\n',
        file = htmloutfile, append = TRUE);
    
    
  }else{
    cat('<br><br><b><font color=red>!!! No replicates found. Cannot perform test to check significance of differential expression. Thus, no Volcano plot generated !!!</font></b><br><br>',
        file = htmloutfile, append = TRUE);
  }
  
}


#***************************************************************************************************************************************
# Functions: End
#***************************************************************************************************************************************


#===============================================================================
# Arguments
#===============================================================================

volc_with = args[10];

htmloutfile = args[11]; # html output file
outdir = args[12]; # html supporting files

#===============================================================================
# Check for file existance
#===============================================================================
if(! file.exists(proteome_file))
{

suppressPackageStartupMessages(library(dplyr));
suppressPackageStartupMessages(library(data.table));
suppressPackageStartupMessages(library(gplots));
suppressPackageStartupMessages(library(ggplot2));
suppressPackageStartupMessages(library(ggfortify));
suppressPackageStartupMessages(library(plotly));
suppressPackageStartupMessages(library(d3heatmap));

#===============================================================================
# Select mode and parse experiment design file
#===============================================================================
if(mode=="multiple")
{
  expDesign = fread(sampleinfo_file, header = FALSE, stringsAsFactors = FALSE, sep="\t") %>% data.frame();
  expDesign_cc = expDesign[1:2,];
  
  sampleinfo_df = expDesign[3:nrow(expDesign),];
  rownames(sampleinfo_df)=1:nrow(sampleinfo_df);
  colnames(sampleinfo_df) =  c("Sample","Group");
  
  condition_cols = sampleinfo_df[which(sampleinfo_df[,2]==expDesign_cc[which(expDesign_cc[,1]=="case"),2]),1];
  condition_g_name = "case";
  control_cols = sampleinfo_df[which(sampleinfo_df[,2]==expDesign_cc[which(expDesign_cc[,1]=="control"),2]),1];
  control_g_name = "control";
  sampleinfo_df[which(sampleinfo_df[,2]==expDesign_cc[which(expDesign_cc[,1]=="case"),2]),2] = "case";
  sampleinfo_df[which(sampleinfo_df[,2]==expDesign_cc[which(expDesign_cc[,1]=="control"),2]),2] = "control";
  sampleinfo_df_orig = sampleinfo_df;
}

if(mode=="logfold")
{
  sampleinfo_df = data.frame("Sample"= c("LogFold"), "Group"=c("Fold_Change"))
}

#===============================================================================
# Parse Transcriptome data
#===============================================================================
TE_df_orig = fread(transcriptome_file, sep="\t", stringsAsFactor=F, header=T) %>% data.frame();
if(mode=="multiple")
{
  TE_df = TE_df_orig[,c(colnames(TE_df_orig)[1],condition_cols,control_cols)];
}
if(mode=="logfold")
{
  TE_df = TE_df_orig;
  colnames(TE_df) = c("Genes", "LogFold");
}
#===============================================================================
# Parse Proteome data
#===============================================================================
PE_df_orig = fread(proteome_file, sep="\t", stringsAsFactor=F, header=T) %>% data.frame();
if(mode=="multiple")
{
  PE_df = PE_df_orig[,c(colnames(PE_df_orig)[1],condition_cols,control_cols)];
}
if(mode=="logfold")
{
  PE_df = PE_df_orig;
  colnames(PE_df) = c("Genes", "LogFold");
}

#=============================================================================================================
# Create directory structures and then set the working directory to output directory
#=============================================================================================================

  dir.create(outdir);
}
#===============================================================================
# Write initial data summary in html outfile
#===============================================================================
cat("<html><head></head><body>\n", file = htmloutfile);

cat("<h1><u>QuanTP: Association between abundance ratios of transcript and protein</u></h1><hr/>\n",
    "<font><h3>Input data summary</h3></font>\n",
    "<ul>\n",
    "<li>Abbreviations used: PE (Proteome data) and TE (Transcriptome data)","</li><br>\n",
    "<li>Input Proteome data dimension (Row Column): ", dim(PE_df)[1]," x ", dim(PE_df)[2],"</li>\n",
    "<li>Input Transcriptome data dimension (Row Column): ", dim(TE_df)[1]," x ", dim(TE_df)[2],"</li></ul><hr/>\n",
    file = htmloutfile, append = TRUE);

cat("<h3 id=table_of_content>Table of Contents:</h3>\n",
    "<ul>\n",
    "<li><a href=#sample_dist>Sample distribution</a></li>\n",
    "<li><a href=#corr_data>Correlation</a></li>\n",
    "<li><a href=#regression_data>Regression analysis</a></li>\n",
    "<li><a href=#inf_obs>Influential observations</a></li>\n",

PE_nacount = sum(is.na(PE_df));

TE_df[is.na(TE_df)] = 0;
PE_df[is.na(PE_df)] = 0;

#===============================================================================
# Obtain JS/HTML lines for interactive visualization
#===============================================================================
extractWidgetCode = function(outplot){
  lines <- readLines(gsub("\\.png", "\\.html", outplot))
  return(list(
    'prescripts'  = c('',
                      gsub('script', 'script',
                           lines[grep('<head>',lines) + 3
                                 :grep('</head>' ,lines) - 5]),
                      ''),
    'widget_div'  = paste('<!--',
                          gsub('width:100%;height:400px',
                               'width:500px;height:500px',
                               lines[grep(lines, pattern='html-widget')]),
                          '-->', sep=''),
    'postscripts' = paste('',
                          gsub('script', 'script',
                               lines[grep(lines, pattern='<script type')]),
                          '', sep='')));
}
prescripts <- list()
postscripts <- list()


#===============================================================================
# Decide based on analysis mode
#===============================================================================
if(mode=="logfold")
{
  cat('<h2 id="sample_dist"><font color=#ff0000>SAMPLE DISTRIBUTION</font></h2>\n',
      file = htmloutfile, append = TRUE);
  
  # TE Boxplot
  outplot = paste(outdir,"/Box_TE.png",sep="",collape="");
  cat('<table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; ">\n',
      '<tr bgcolor="#7a0019"><th><font color=#ffcc33>Boxplot: Transcriptome data</font></th><th><font color=#ffcc33>Boxplot: Proteome data</font></th></tr>\n',
      "<tr><td align=center>", '<img src="Box_TE.png" width=500 height=500></td>\n', file = htmloutfile, append = TRUE);
  multisample_boxplot(TE_df, sampleinfo_df, outplot, "Yes", "Samples", "Transcript Abundance data");
  
  # PE Boxplot
  outplot = paste(outdir,"/Box_PE.png",sep="",collape="");
  cat("<td align=center>", '<img src="Box_PE.png" width=500 height=500></td></tr></table>\n', file = htmloutfile, append = TRUE);
  multisample_boxplot(PE_df, sampleinfo_df, outplot, "Yes", "Samples", "Protein Abundance data");
  
  cat('<hr/><h2 id="corr_data"><font color=#ff0000>CORRELATION</font></h2>\n',
      file = htmloutfile, append = TRUE);
  
  # TE PE scatter
  outplot = paste(outdir,"/TE_PE_scatter.png",sep="",collape="");
  cat('<table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Scatter plot between Proteome and Transcriptome Abundance</font></th></tr>\n', file = htmloutfile, append = TRUE);
  singlesample_scatter(PE_TE_data, outplot);  
  lines <- extractWidgetCode(outplot);
  postscripts <- c(postscripts, lines$postscripts);
  cat("<tr><td align=center>", '<img src="TE_PE_scatter.png" width=800 height=800>', lines$widget_div, '</td></tr>\n', file = htmloutfile, append = TRUE);
  PE_TE_data = data.frame(PE_df, TE_df);
  colnames(PE_TE_data) = c("PE_ID","PE_abundance","TE_ID","TE_abundance");
  
  # TE PE Cor
  cat("<tr><td align=center>", file = htmloutfile, append = TRUE);
  singlesample_cor(PE_TE_data, htmloutfile, append=TRUE);
  cat('<font color="red">*Note that <u>correlation</u> is <u>sensitive to outliers</u> in the data. So it is important to analyze outliers/influential observations in the data.<br> Below we use <u>Cook\'s distance based approach</u> to identify such influential observations.</font>\n',
      file = htmloutfile, append = TRUE);
  cat('</td></table>',
      file = htmloutfile, append = TRUE);
  
  cat('<hr/><h2 id="regression_data"><font color=#ff0000>REGRESSION ANALYSIS</font></h2>\n',
      file = htmloutfile, append = TRUE);
  
  # TE PE Regression
  singlesample_regression(PE_TE_data,htmloutfile, append=TRUE);
  postscripts <- c(postscripts, c(extractWidgetCode(paste(outdir,"/PE_TE_lm_1.png",sep="",collapse=""))$postscripts,
                                  extractWidgetCode(paste(outdir,"/PE_TE_lm_2.png",sep="",collapse=""))$postscripts,
                                  extractWidgetCode(paste(outdir,"/PE_TE_lm_5.png",sep="",collapse=""))$postscripts,
                                  extractWidgetCode(paste(outdir,"/PE_TE_lm_cooksd.png",sep="",collapse=""))$postscripts,
                                  extractWidgetCode(paste(outdir,"/AbundancePlot_scatter_without_outliers.png",sep="",collapse=""))$postscripts));
  
  cat('<hr/><h2 id="cluster_data"><font color=#ff0000>CLUSTER ANALYSIS</font></h2>\n',
      file = htmloutfile, append = TRUE);
  
  # TE PE Heatmap
  singlesample_heatmap(PE_TE_data, htmloutfile, hm_nclust);
  lines <- extractWidgetCode(paste(outdir,"/PE_TE_heatmap.png",sep="",collapse=""))
  postscripts <- c(postscripts, lines$postscripts)
  prescripts <- c(prescripts, lines$prescripts)
  
  
  # TE PE Clustering (kmeans)
  singlesample_kmeans(PE_TE_data, htmloutfile, nclust=as.numeric(numCluster))
  postscripts <- c(postscripts, extractWidgetCode(paste(outdir,"/PE_TE_kmeans.png",sep="",collapse=""))$postscripts)
  
}else{
  if(mode=="multiple")
  {
    cat('<h2 id="sample_dist"><font color=#ff0000>SAMPLE DISTRIBUTION</font></h2>\n',
        file = htmloutfile, append = TRUE);
    
    # TE Boxplot
    outplot = paste(outdir,"/Box_TE_all_rep.png",sep="",collape="");
    temp_df_te_data = data.frame(TE_df[,1], log(TE_df[,2:length(TE_df)]));
    colnames(temp_df_te_data) = colnames(TE_df);
    multisample_boxplot(temp_df_te_data, sampleinfo_df, outplot, "Yes", "Samples", "Transcript Abundance (log)");
    lines <- extractWidgetCode(outplot)
    prescripts <- c(prescripts, lines$prescripts)
    postscripts <- c(postscripts, lines$postscripts)
    cat('<table  border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; ">\n',
        '<tr bgcolor="#7a0019"><th><font color=#ffcc33>Boxplot: Transcriptome data</font></th><th><font color=#ffcc33>Boxplot: Proteome data</font></th></tr>\n',
        "<tr><td align=center>", file = htmloutfile, append = TRUE);
    cat('<img src="Box_TE_all_rep.png" width=500 height=500>', 
        lines$widget_div, '</td>', file = htmloutfile, append = TRUE);
    
    # PE Boxplot
    outplot = paste(outdir,"/Box_PE_all_rep.png",sep="",collape="");
    temp_df_pe_data = data.frame(PE_df[,1], log(PE_df[,2:length(PE_df)]));
    colnames(temp_df_pe_data) = colnames(PE_df);
    multisample_boxplot(temp_df_pe_data, sampleinfo_df, outplot, "Yes", "Samples", "Protein Abundance (log)");
    lines <- extractWidgetCode(outplot)
    #prescripts <- c(prescripts, lines$prescripts)
    postscripts <- c(postscripts, lines$postscripts)
    cat("<td align=center>", '<img src="Box_PE_all_rep.png" width=500 height=500>',
        lines$widget_div, '</td></tr></table>\n', file = htmloutfile, append = TRUE);
    
    # Calc TE PCA
    outplot = paste(outdir,"/PCA_TE_all_rep.png",sep="",collape="");
    multisample_PCA(TE_df, sampleinfo_df, outplot);
    PCA_TE <- extractWidgetCode(outplot)
    postscripts <- c(postscripts, PCA_TE$postscripts)
    
    # Calc PE PCA
    outplot = paste(outdir,"/PCA_PE_all_rep.png",sep="",collape="");
    multisample_PCA(PE_df, sampleinfo_df, outplot);
    PCA_PE <- extractWidgetCode(outplot)
    postscripts <- c(postscripts, PCA_PE$postscripts)
    
    # Replicate mode
    templist = mergeReplicates(TE_df,PE_df, sampleinfo_df, method);
    TE_df = templist$TE_df_merged;
    PE_df = templist$PE_df_merged;
    sampleinfo_df = templist$sampleinfo_df_merged;
    rownames(sampleinfo_df) = sampleinfo_df[,1];
    
    # TE Boxplot
    outplot = paste(outdir,"/Box_TE_rep.png",sep="",collape="");
    temp_df_te_data = data.frame(TE_df[,1], log(TE_df[,2:length(TE_df)]));
    colnames(temp_df_te_data) = colnames(TE_df);
    multisample_boxplot(temp_df_te_data, sampleinfo_df, outplot, "No", "Sample Groups", "Mean Transcript Abundance (log)");
    lines <- extractWidgetCode(outplot)
    #prescripts <- c(prescripts, lines$prescripts)
    postscripts <- c(postscripts, lines$postscripts)
    cat('<br><font color="#ff0000"><h3>Sample wise distribution (Box plot) after using ',method,' on replicates </h3></font><table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Boxplot: Transcriptome data</font></th><th><font color=#ffcc33>Boxplot: Proteome data</font></th></tr>\n',
        "<tr><td align=center>", '<img src="Box_TE_rep.png" width=500 height=500>', lines$widget_div, '</td>\n', file = htmloutfile, append = TRUE);
    
    # PE Boxplot
    outplot = paste(outdir,"/Box_PE_rep.png",sep="",collape="");
    temp_df_pe_data = data.frame(PE_df[,1], log(PE_df[,2:length(PE_df)]));
    colnames(temp_df_pe_data) = colnames(PE_df);
    multisample_boxplot(temp_df_pe_data, sampleinfo_df, outplot, "No", "Sample Groups", "Mean Protein Abundance (log)");
    lines <- extractWidgetCode(outplot)
    #prescripts <- c(prescripts, lines$prescripts)
    postscripts <- c(postscripts, lines$postscripts)
    cat("<td align=center>", '<img src="Box_PE_rep.png" width=500 height=500>', lines$widget_div, '</td></tr></table>\n', file = htmloutfile, append = TRUE);
    
    #===============================================================================
    # Calculating log fold change and running the "single" code part 
    #===============================================================================
    
    TE_df = data.frame("Genes"=TE_df[,1], "LogFold"=apply(TE_df[,c(which(colnames(TE_df)==condition_g_name),which(colnames(TE_df)==control_g_name))],1,function(x) log(x[1]/x[2],base=2)));
    PE_df = data.frame("Genes"=PE_df[,1], "LogFold"=apply(PE_df[,c(which(colnames(PE_df)==condition_g_name),which(colnames(PE_df)==control_g_name))],1,function(x) log(x[1]/x[2],base=2)));
    
    #===============================================================================
    # Treat missing values
    #===============================================================================
    
    TE_df[is.infinite(TE_df[,2]),2] = NA;
    PE_df[is.infinite(PE_df[,2]),2] = NA;
    TE_df[is.na(TE_df)] = 0;
    PE_df[is.na(PE_df)] = 0;
    
    sampleinfo_df = data.frame("Sample"= c("LogFold"), "Group"=c("Fold_Change"))
    #===============================================================================
    # Find common samples
    #===============================================================================
    
    common_samples = intersect(sampleinfo_df[,1], colnames(TE_df)[-1]) %>% intersect(., colnames(PE_df)[-1]);
    TE_df =  select(TE_df, 1, common_samples);
    PE_df =  select(PE_df, 1, common_samples);
    sampleinfo_df = filter(sampleinfo_df, Sample %in% common_samples);
    rownames(sampleinfo_df) = sampleinfo_df[,1];
    
    # TE Boxplot
    outplot = paste(outdir,"/Box_TE.png",sep="",collape="");
    multisample_boxplot(TE_df, sampleinfo_df, outplot, "Yes", "Sample (log2(case/control))", "Transcript Abundance fold-change (log2)");
    lines <- extractWidgetCode(outplot)
    postscripts <- c(postscripts, lines$postscripts)
    cat('<br><font color="#ff0000"><h3>Distribution (Box plot) of log fold change </h3></font>', file = htmloutfile, append = TRUE);
    cat('<table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Boxplot: Transcriptome data</font></th><th><font color=#ffcc33>Boxplot: Proteome data</font></th></tr>\n',
        "<tr><td align=center>", '<img src="Box_TE.png" width=500 height=500>', lines$widget_div, '</td>\n', file = htmloutfile, append = TRUE);
    
    # PE Boxplot
    outplot = paste(outdir,"/Box_PE.png",sep="",collape="");
    multisample_boxplot(PE_df, sampleinfo_df, outplot, "Yes", "Sample (log2(case/control))", "Protein Abundance fold-change(log2)");
    lines <- extractWidgetCode(outplot)
    postscripts <- c(postscripts, lines$postscripts)
    cat("<td align=center>", '<img src="Box_PE.png" width=500 height=500>', lines$widget_div,'</td></tr></table>\n', file = htmloutfile, append = TRUE);
    
    
    # Log Fold Data
    perform_Test_Volcano(TE_df_orig,PE_df_orig,TE_df, PE_df,sampleinfo_df_orig,method,correction_method,volc_with)
    postscripts <- c(postscripts, extractWidgetCode(paste(outdir,"/TE_volcano.png",sep="",collapse=""))$postscripts)
    postscripts <- c(postscripts, extractWidgetCode(paste(outdir,"/PE_volcano.png",sep="",collapse=""))$postscripts)
    
    # Print PCA
    
    cat('<br><br><table  border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>PCA plot: Transcriptome data</font></th><th><font color=#ffcc33>PCA plot: Proteome data</font></th></tr>\n',
        "<tr><td align=center>", '<img src="PCA_TE_all_rep.png" width=500 height=500>', PCA_TE$widget_div, '</td>\n',
        "<td align=center>", '<img src="PCA_PE_all_rep.png" width=500 height=500>', PCA_PE$widget_div, '</td></tr></table>\n', 
        file = htmloutfile, append = TRUE);
    
    
    
    cat('<hr/><h2 id="corr_data"><font color=#ff0000>CORRELATION</font></h2>\n',
        file = htmloutfile, append = TRUE);
    
    PE_TE_data = data.frame(PE_df, TE_df);
    colnames(PE_TE_data) = c("PE_ID","PE_abundance","TE_ID","TE_abundance");
    
    # TE PE scatter
    outplot = paste(outdir,"/TE_PE_scatter.png",sep="",collape="");
    cat('<br><table border=1 cellspacing=0 cellpadding=5 style="table-layout:auto; "> <tr bgcolor="#7a0019"><th><font color=#ffcc33>Scatter plot between Proteome and Transcriptome Abundance</font></th></tr>\n', file = htmloutfile, append = TRUE);
    singlesample_scatter(PE_TE_data, outplot);  
    lines <- extractWidgetCode(outplot);
    postscripts <- c(postscripts, lines$postscripts);  
    cat("<tr><td align=center>", '<img src="TE_PE_scatter.png" width=800 height=800>', gsub('width:500px;height:500px', 'width:800px;height:800px' , lines$widget_div),
        '</td>\n', file = htmloutfile, append = TRUE);
    
    # TE PE Cor
    cat("<tr><td align=center>\n", file = htmloutfile, append = TRUE);
    singlesample_cor(PE_TE_data, htmloutfile, append=TRUE);
    cat('<font color="red">*Note that <u>correlation</u> is <u>sensitive to outliers</u> in the data. So it is important to analyze outliers/influential observations in the data.<br> Below we use <u>Cook\'s distance based approach</u> to identify such influential observations.</font>\n',
        file = htmloutfile, append = TRUE);
    cat('</td></table>',
        file = htmloutfile, append = TRUE);
    
    cat('<hr/><h2 id="regression_data"><font color=#ff0000>REGRESSION ANALYSIS</font></h2>\n',
        file = htmloutfile, append = TRUE);
    
    # TE PE Regression
    singlesample_regression(PE_TE_data,htmloutfile, append=TRUE);
    postscripts <- c(postscripts, c(extractWidgetCode(paste(outdir,"/PE_TE_lm_1.png",sep="",collapse=""))$postscripts,
                                    extractWidgetCode(paste(outdir,"/PE_TE_lm_2.png",sep="",collapse=""))$postscripts,
                                    extractWidgetCode(paste(outdir,"/PE_TE_lm_5.png",sep="",collapse=""))$postscripts,
                                    extractWidgetCode(paste(outdir,"/PE_TE_lm_cooksd.png",sep="",collapse=""))$postscripts,
                                    extractWidgetCode(paste(outdir,"/AbundancePlot_scatter_without_outliers.png",sep="",collapse=""))$postscripts,
                                    gsub('data-for="html', 'data-for="secondhtml"', 
                                         extractWidgetCode(paste(outdir,"/TE_PE_scatter.png",sep="",collapse=""))$postscripts)));
    
    cat('<hr/><h2 id="cluster_data"><font color=#ff0000>CLUSTER ANALYSIS</font></h2>\n',
        file = htmloutfile, append = TRUE);
    
    #TE PE Heatmap
    singlesample_heatmap(PE_TE_data, htmloutfile, hm_nclust);
    lines <- extractWidgetCode(paste(outdir,"/PE_TE_heatmap.png",sep="",collapse=""))
    postscripts <- c(postscripts, lines$postscripts)
    prescripts <- c(prescripts, lines$prescripts)
    
    #TE PE Clustering (kmeans)
    singlesample_kmeans(PE_TE_data, htmloutfile, nclust=as.numeric(numCluster))
    postscripts <- c(postscripts, extractWidgetCode(paste(outdir,"/PE_TE_kmeans.png",sep="",collapse=""))$postscripts);
  }
}
cat("<h3>Go To:</h3>\n",
    "<ul>\n",
    "<li><a href=#sample_dist>Sample distribution</a></li>\n",

    "<li><a href=#inf_obs>Influential observations</a></li>\n",
    "<li><a href=#cluster_data>Cluster analysis</a></li></ul>\n",
    "<br><a href=#>TOP</a>",
    file = htmloutfile, append = TRUE);
cat("</body></html>\n", file = htmloutfile, append = TRUE);


#===============================================================================
# Add masked-javascripts tags to HTML file in the head and end
#===============================================================================

htmllines <- readLines(htmloutfile)
htmllines[1] <- paste('<html>\n<head>\n', paste(prescripts, collapse='\n'), '\n</head>\n<body>')
cat(paste(htmllines, collapse='\n'), file = htmloutfile)
cat('\n', paste(postscripts, collapse='\n'), "\n",
    "</body>\n</html>\n", file = htmloutfile, append = TRUE);