Statistical Algorithms Importer: Create Project

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Revision as of 19:44, 13 October 2016 by Gianpaolo.coro (Talk | contribs) (Input)

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This page explains how to create a project using Statistical Algorithms Importer(SAI) portlet.

Project Folder

The fist step is to create or select an empty folder on the e-Infrastructure Workspace. Then, using the Create Project button in the main menu, the system creates an empty project in that folder.
Create Project, SAI

Import Resources

Any resource needed to run the script can be imported in the Project Folder. Resources cab be added either via the Workspace or using the Add Resource button in main menu, or dragging and dropping files in the folder window.
Add Resource, SAI
Thus, if the resource is on the user's local file system, (s)he can use the Drag and Drop facility, working also with multiple files.
Adding resources with Drag and Drop, SAI

Import Resources From GitHub

If you have a project on GitHub, you can import it into SAI. After creating a new project, just click the menu button on GitHub.
GitHub on Menu, SAI
You may access the GitHub Connector wizard. Please, read here to see how to use it: GitHub Connector

Set Main Code

After adding the scripts and resources, one of the script files should be indicated as Main code. The e-Infrastructure will run this code, which is supposed to import and orchestrate the other scripts. Indicating a script as Main code can be done by clicking the Set Main button in Project Explorer. The file will be loaded in the Editor. In this phase the system also reads possible annotations inside the script (e.g. WPS4R annotations). At this point, the user can change the code and save it using the Save button on the Editor panel. Alternatively, the user can also use Copy and Paste by writing the code directly in the editor and then save it, still using the Save button in Editor menu (A file name will be requested).
Set Main Code facility, SAI

Input

In this area the system collects all the information required by the system to create software for the e-Infrastructure and communicate with the e-Infrastructure team. Metadata, input/output information, global parameters and required packages are collected here.

Global Variables

In this panel you can add any Global Variable that are used by the script as pre-requisite.
Global Variables indication, SAI

Input/Output

In this area, selected input and output from the script is collected. In order to add a new I/O, the user should select a row in the code (from the the Editor) and than click the +Input (or +Output) button in the Menu Editor.

A new row is added to the Input/Output list. The system parses the code behind the scenes and guesses the best type, description and name of the parameter. Once a row has been created in the Input/Output window, the user can change information by clicking on the row. At least one input is required for compiling the project. The name of the input variable and the default value should not be changed unless a parsing error occurred. The reason is that the infrastructure will discover the variables inside the script by using the name and the default value.

Note: as a general rule, always set a default value for a variable, otherwise the execution of the algorithm may be compromised. Thus, do not use empty strings as default values.

Input/Output window, SAI
A description of advanced cases can be found in Advanced Input .

Advanced Input

It is possible to indicate spatial inputs or time/date inputs. The details for the definition of these dare are reported in the Advanced Input page.

Interprer Info

You can add Version and Packages information in the Interpreter Info panel. The version number is mandatory for the project. Here, for example, a user should specify the version of the R interpreter and the packages needed to run the script. These will be installed on the e-Infrastructure machines during the first deployment session.
Interpreter Info, SAI

Project Info

A name and a description of the project are mandatory. These will be displayed to the user of the e-Infrastructure and should also contain proper citation of the algorithm. Special characters are not allowed for the algorithm name. The user can include a list of the VREs this algorithm should be visible to.
Project Info, SAI

Save Project

You can save project by click on Save button in main menu. A file called stat_algo.project is add to Project Folder.
Save Project, SAI


Using WPS4R Annotations

SAI automatically parses R code containing WPS4R annotations, the system automatically transforms annotations into Input/Output panel and Project Info panel information. The name of algorithm is mandatory in the annotations. We report a full example of annotated algorithm and attach the complete algorithm in a zip package:
############################################################################################################################
############# Absence Generation Script - Gianpaolo Coro and Chiara Magliozzi, CNR 2015, Last version 06-07-2015 ###########
############################################################################################################################

#52North WPS annotations
# wps.des: id = Absence_generation_from_OBIS, title = Absence_generation_from_OBIS, abstract = A script to estimate absence records from OBIS;

rm(list=ls(all=TRUE))
graphics.off() 

## charging the libraries
library(DBI)
library(RPostgreSQL)
library(raster)
library(maptools)

# time
t0<-Sys.time()

## parameters 
# wps.in: id = list, type = text/plain, title = list of species beginning with the speciesname header,value="species.txt";
list= "species.txt"
specieslist<-read.table(list,header=T,sep=",") # my short dataset 2 species
#attach(specieslist)
# wps.in: id = res, type = double, title = resolution of the analysis,value=1;
res=1;
extent_x=180
extent_y=90
n=extent_y*2/res;
m=extent_x*2/res;
# wps.in: id = occ_percentage, type = double, title = percentage of observations occurrence of a viable survey,value=0.1;
occ_percentage=0.1 #between 0 and 1

#uncomment for time filtering

#No time filter
TimeStart<-"";
TimeEnd<-"";

TimeStart<-gsub("(^ +)|( +$)", "",TimeStart)
TimeEnd<-gsub("(^ +)|( +$)", "", TimeEnd)

## opening the connection with postgres
cat("Opening the connection with the catalog\n")
drv <- dbDriver("PostgreSQL")
con <- dbConnect(drv, dbname="", host="", port="5432", user="", password="")

cat("Analyzing the list of species\n")
counter=0;
overall=length(specieslist$scientificname)

cat("Extraction from the different contributors the total number of obs per resource id...\n")

timefilter<-""
if (nchar(TimeStart)>0 && nchar(TimeEnd)>0)
  timefilter<-paste(" where datecollected>'",TimeStart,"' and datecollected<'",TimeEnd,"'",sep="");

queryCache <- paste("select drs.resource_id, count(distinct position_id) as allcount from obis.drs", timefilter, " group by drs.resource_id",sep="")
cat("Resources extraction query:",queryCache,"\n")

allresfile="allresources.dat"
if (file.exists(allresfile)){
  load(allresfile)
} else{
  allresources1<-dbGetQuery(con,queryCache)
  save(allresources1,file=allresfile)
}

files<-vector()
f<-0
dir.create("data")

for (sp in specieslist$scientificname){
  f<-f+1
  t1<-Sys.time()
  graphics.off()
  grid=matrix(data=0,nrow=n,ncol=m)
  gridInfo=matrix(data="",nrow=n,ncol=m)
  outputfileAbs=paste("data/Absences_",sp,"_",res,"deg.csv",sep="");
  outputimage=paste("data/Absences_",sp,"_",res,"deg.png",sep="");
  
  counter=counter+1;
  cat("analyzing species",sp,"\n")
  cat("***Species status",counter,"of",overall,"\n")
  
  ## first query: select the species
  cat("Extraction the species id from the OBIS database...\n")
  query1<-paste("select id from obis.tnames where tname='",sp,"'", sep="")
  obis_id<- dbGetQuery(con,query1)
  cat("The ID extracted is ", obis_id$id, "for the species", sp, "\n", sep=" ")
  
  if (nrow(obis_id)==0) {
    cat("WARNING: there is no reference code for", sp,"\n")
    next;
  }
  
  ## second query: select the contributors
  cat("Selection of the contributors in the database having recorded the species...\n")
  query2<- paste("select distinct resource_id from obis.drs where valid_id='",obis_id$id,"'", sep="")
  posresource<-dbGetQuery(con,query2)
  
  if (nrow(posresource)==0) {
    cat("WARNING: there are no resources for", sp,"\n")
    next;
  }
  
  
  ## third query: select from the contributors different observations
  merge(allresources1, posresource, by="resource_id")-> res_ids
  
  ## forth query: how many obs are contained in each contributors for the species
  cat("Extraction from the different contributors the number of obs for the species...\n")
  query4 <- paste("select drs.resource_id, count(distinct position_id) as tgtcount from obis.drs where valid_id='",obis_id,"'group by drs.resource_id ",sep="")
  tgtresources1<-dbGetQuery(con,query4)
  merge(tgtresources1, posresource, by="resource_id")-> tgtresourcesSpecies 
  
  ## fifth query: select contributors that has al least 0.1 observation of the species
  #### we have the table all together: contributors, obs in each contributors for at leat one species and obs of the species in each contributors
  cat("Extracting the contributors containing more than 10% of observations for the species\n")
  tmp <- merge(res_ids, tgtresourcesSpecies, by= "resource_id",all.x=T)
  tmp["species_10"] <- NA 
  tmp$tgtcount / tmp$allcount -> tmp$species_10
  
  viable_res_ids <- subset(tmp,species_10 >= occ_percentage, select=c("resource_id","allcount","tgtcount", "species_10")) 
  #cat(viable_res_ids)
  
  if (nrow(viable_res_ids)==0) {
    cat("WARNING: there are no viable points for", sp,"\n")
    next;
  }
  
  numericselres<-paste("'",paste(as.character(as.numeric(t(viable_res_ids["resource_id"]))),collapse="','"),"'",sep="")
  
  ## sixth query: select all the cell at 0.1 degrees resolution in the main contributors
  cat("Select the cells at 0.1 degrees resolution for the main contributors\n")
  query6 <- paste("select position_id, positions.latitude, positions.longitude, count(*) as allcount ", 
                  "from obis.drs ", 
                  "inner join obis.tnames on drs.valid_id=tnames.id ",
                  "inner join obis.positions on position_id=positions.id ",
                  "where resource_id in (", numericselres,") ",
                  "group by position_id, positions.latitude, positions.longitude, resource_id")
  all_cells <- dbGetQuery(con,query6)
  
  ## seventh query:  select all the cell at 0.1 degrees resolution in the main contributors for the selected species
  cat("Select the cells at 0.1 degrees resolution for the species in the main contributors\n")
  query7 <- paste("select position_id, positions.latitude, positions.longitude, count(*) as tgtcount ",
                  "from obis.drs",
                  "inner join obis.tnames on drs.valid_id=tnames.id ", 
                  "inner join obis.positions on position_id=positions.id ", 
                  "where resource_id in (", numericselres,") ",
                  "and drs.valid_id='",obis_id,"'", 
                  "group by position_id, positions.latitude, positions.longitude")
  presence_cells<-dbGetQuery(con,query7)
  
  ## last query: for every cell in the sixth query if there is a correspondent in the seventh query I can put 1 otherwise 0
  data.df<-merge(all_cells, presence_cells, by= "position_id",all.x=T)
  data.df$longitude.y<-NULL 
  data.df$latitude.y<-NULL
  data.df[is.na(data.df)] <- 0 
  
  ######### Table resulting from the analysis
  pres_abs_cells <- subset(data.df,select=c("latitude.x","longitude.x", "tgtcount","position_id"))
  positions<-paste("'",paste(as.character(as.numeric(t(pres_abs_cells["position_id"]))),collapse="','"),"'",sep="")
  
  query8<-paste("select position_id, resfullname,digirname,abstract,temporalscope,date_last_harvested",
                "from ((select distinct position_id,resource_id from obis.drs where position_id IN (", positions,
                ") order by position_id ) as a",
                "inner join (select id,resfullname,digirname,abstract,temporalscope,date_last_harvested from obis.resources where id in (",
                numericselres,")) as b on b.id = a.resource_id) as d")
  
  resnames<-dbGetQuery(con,query8)
  #sorting data df
  pres_abs_cells<-pres_abs_cells[with(pres_abs_cells, order(position_id)), ]
  
  nrows = nrow(pres_abs_cells)
  ######## FIRST Loop inside the rows of the dataset
  cat("Looping on the data\n")
  for(i in 1: nrows) {
    lat<-pres_abs_cells[i,1]
    long<-pres_abs_cells[i,2]
    value<-pres_abs_cells[i,3]
    resource_name<-paste("\"",paste(as.character(t(resnames[i,])),collapse="\",\""),"\"",sep="")#resnames[i,2]
    k=round((lat+90)*n/180)
    g=round((long+180)*m/360)
    if (k==0) k=1;
    if (g==0) g=1;
    if (k>n || g>m)
      next;
    if (value>=1){
      if (grid[k,g]==0){
        grid[k,g]=1
        gridInfo[k,g]=resource_name
      }
      else if (grid[k,g]==-1){
        grid[k,g]=-2
        gridInfo[k,g]=resource_name
      }
    }
    else if (value==0){
      if (grid[k,g]==0){
        grid[k,g]=-1
        #cat("resource abs",resource_name,"\n")
        gridInfo[k,g]=resource_name
      }
      else if (grid[k,g]==1){
        grid[k,g]=-2
        gridInfo[k,g]=resource_name
      }
      
    }
  }
  cat("End looping\n")
  
  cat("Generating image\n")
  absence_cells<-which(grid==-1,arr.ind=TRUE)
  presence_cells_idx<-which(grid==1,arr.ind=TRUE)
  latAbs<-((absence_cells[,1]*180)/n)-90
  longAbs<-((absence_cells[,2]*360)/m)-180
  latPres<-((presence_cells_idx[,1]*180)/n)-90
  longPres<-((presence_cells_idx[,2]*360)/m)-180
  resource_abs<-gridInfo[absence_cells]
  
  absPoints <- cbind(longAbs, latAbs)
  absPointsData <- cbind(longAbs, latAbs,resource_abs)
  
  if (length(absPoints)==0)
  {
    cat("WARNING no viable point found for ",sp," after processing!\n")
    next;
  }
  data(wrld_simpl)
  projection(wrld_simpl) <- CRS("+proj=longlat")
  png(filename=outputimage, width=1200, height=600)
  plot(wrld_simpl, xlim=c(-180, 180), ylim=c(-90, 90), axes=TRUE, col="black")
  box()
  pts <- SpatialPoints(absPoints,proj4string=CRS(proj4string(wrld_simpl)))
  
  ## Find which points do not fall over land
  cat("Retreiving the poing that do not fall on land\n")
  pts<-pts[which(is.na(over(pts, wrld_simpl)$FIPS))]
  points(pts, col="green", pch=1, cex=0.50)
  datapts<-as.data.frame(pts)
  colnames(datapts) <- c("longAbs","latAbs")
  
  abspointstable<-merge(datapts, absPointsData, by.x= c("longAbs","latAbs"), by.y=c("longAbs","latAbs"),all.x=F)
  
  
  header<-"longitude,latitude,resource_id,resource_name,resource_identifier,resource_abstract,resource_temporalscope,resource_last_harvested_date"
  write.table(header,file=outputfileAbs,append=F,row.names=F,quote=F,col.names=F)
  
  write.table(abspointstable,file=outputfileAbs,append=T,row.names=F,quote=F,col.names=F,sep=",")
  files[f]<-outputfileAbs
  cat("Elapsed:  created imaged in ",Sys.time()-t1," sec \n")
  graphics.off()
}

# wps.out: id = zipOutput, type = text/zip, title = zip file containing absence records and images;
zipOutput<-"absences.zip"
zip(zipOutput, files=c("./data"), flags= "-r9X", extras = "",zip = Sys.getenv("R_ZIPCMD", "zip"))

cat("Closing database connection")
cat("Elapsed:  overall process finished in ",Sys.time()-t0," min \n")
dbDisconnect(con)
graphics.off()

File:AbsencesSpeciesList prod annotated.zip


The following screenshot report the result of importing this script into SAI:
Annotations Project Info, SAI
Annotations Input/Output, SAI