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authorDannyArends2016-11-07 16:56:30 +0100
committerDannyArends2016-11-07 16:56:30 +0100
commit65699e8bd17b41a83d1d5013dd81e4328b4d3797 (patch)
tree1a8cd09fcc5dd301d24e6139403e5d568a4fef22 /wqflask
parentecdb906b3bb43c9b8e863b434ff63d444d439a65 (diff)
downloadgenenetwork2-65699e8bd17b41a83d1d5013dd81e4328b4d3797.tar.gz
Adding code to the ctl analysis file to output nodes and edges for cytoscape
Diffstat (limited to 'wqflask')
-rw-r--r--wqflask/wqflask/ctl/ctl_analysis.py51
1 files changed, 48 insertions, 3 deletions
diff --git a/wqflask/wqflask/ctl/ctl_analysis.py b/wqflask/wqflask/ctl/ctl_analysis.py
index 7a42b2f8..e21b8500 100644
--- a/wqflask/wqflask/ctl/ctl_analysis.py
+++ b/wqflask/wqflask/ctl/ctl_analysis.py
@@ -6,6 +6,8 @@ import scipy as sp # SciPy
import rpy2.robjects as ro # R Objects
import rpy2.rinterface as ri
+import simplejson as json
+
from base.webqtlConfig import GENERATED_IMAGE_DIR
from utility import webqtlUtil # Random number for the image
from utility import genofile_parser # genofile_parser
@@ -73,6 +75,8 @@ class CTL(object):
self.r_CTLnetwork = ro.r["CTLnetwork"] # Map the CTLnetwork function
self.r_CTLprofiles = ro.r["CTLprofiles"] # Map the CTLprofiles function
self.r_plotCTLobject = ro.r["plot.CTLobject"] # Map the CTLsignificant function
+ self.nodes_list = []
+ self.edges_list = []
print("Obtained pointers to CTL functions")
def run_analysis(self, requestform):
@@ -99,7 +103,7 @@ class CTL(object):
genofilelocation = locate(dataset.group.name + ".geno", "genotype")
parser = genofile_parser.ConvertGenoFile(genofilelocation)
parser.process_csv()
-
+ print(dataset.group)
# Create a genotype matrix
individuals = parser.individuals
markers = []
@@ -129,9 +133,11 @@ class CTL(object):
rPheno = r_t(ro.r.matrix(r_as_numeric(r_unlist(traits)), nrow=len(self.trait_db_list), ncol=len(individuals), dimnames = r_list(self.trait_db_list, individuals), byrow=True))
+ print(rPheno)
+
# Use a data frame to store the objects
- rPheno = r_data_frame(rPheno)
- rGeno = r_data_frame(rGeno)
+ rPheno = r_data_frame(rPheno, check_names = False)
+ rGeno = r_data_frame(rGeno, check_names = False)
# Debug: Print the genotype and phenotype files to disk
#r_write_table(rGeno, "~/outputGN/geno.csv")
@@ -169,6 +175,44 @@ class CTL(object):
# Flush any output from R
sys.stdout.flush()
+ # Create the interactive graph for cytoscape visualization (Nodes)
+ # TODO DA : make this a function
+ for trait in self.trait_db_list:
+ if trait != "":
+ ts = trait.split(':')
+ gt = TRAIT.GeneralTrait(name = ts[0], dataset_name = ts[1])
+ node_dict = { 'data' : {'id' : str(gt.name) + ":" + str(gt.dataset.name),
+ 'sid' : str(gt.name),
+ 'dataset' : str(gt.dataset.name),
+ 'label' : gt.name,
+ 'symbol' : gt.symbol,
+ 'geneid' : gt.geneid,
+ 'omim' : gt.omim } }
+ self.nodes_list.append(node_dict)
+
+ # Create the interactive graph for cytoscape visualization (Edges)
+ # TODO DA : make this a function
+ print(type(significant))
+ if not type(significant) == ri.RNULLType:
+ for x in range(len(significant[0])):
+ print(significant[0][x], significant[1][x], significant[2][x]) # Debug to console
+ tsS = significant[0][x].split(':') # Source
+ tsT = significant[2][x].split(':') # Target
+ gtS = TRAIT.GeneralTrait(name = tsS[0], dataset_name = tsS[1]) # Retrieve Source info from the DB
+ gtT = TRAIT.GeneralTrait(name = tsT[0], dataset_name = tsT[1]) # Retrieve Target info from the DB
+ edge_data = {'id' : str(gtS.symbol) + '_' + significant[1][x] + '_' + str(gtT.symbol),
+ 'source' : str(gtS.name) + ":" + str(gtS.dataset.name),
+ 'target' : str(gtT.name) + ":" + str(gtT.dataset.name),
+ 'lod' : significant[3][x],
+ 'color' : "#ff0000",
+ 'width' : significant[3][x] }
+ edge_dict = { 'data' : edge_data }
+ self.edges_list.append(edge_dict)
+ significant[0][x] = gtS.symbol + " (" + gtS.name + ")"
+ significant[2][x] = gtT.symbol + " (" + gtT.name + ")"
+
+ self.elements = json.dumps(self.nodes_list + self.edges_list)
+
def loadImage(self, path, name):
print("pre-loading imgage results:", self.results[path])
imgfile = open(self.results[path], 'rb')
@@ -188,6 +232,7 @@ class CTL(object):
print("Processing CTL output")
template_vars = {}
template_vars["results"] = self.results
+ template_vars["elements"] = self.elements
self.render_image(self.results)
sys.stdout.flush()
return(dict(template_vars))