def moke_consumnes():
calsimfile = getAttr("CALSIMFILE")
f = opendss(calsimfile) # open CALSIM file
outfile = getAttr("BOUNDARYFILE")
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
tw = prepro_window()
moke_us_path = calsim_path("I504")
moke_ref = findpath(f, moke_us_path)
if (moke_ref and len(moke_ref) > 0):
print "Upstream mokelumne flow found, not calculated"
consumnes_path = calsim_path("C501")
moke_ds_path = calsim_path("C504")
consumnes_ref = findpath(f, consumnes_path)
if not consumnes_ref:
raise "Consumnes path %s not found" % consumnes_path
moke_ds_ref = findpath(f, moke_ds_path)
if not moke_ds_ref:
raise "Mokulemne downstream path %s not found" % moke_ds_path
consumnes = DataReference.create(consumnes_ref[0], tw).getData()
moke_ds = DataReference.create(moke_ds_ref[0], tw).getData()
mf = calsim_study_fpart(modify=1)
moke_us_path = calsim_path("I504", mf)
moke_us = moke_ds - consumnes
writedss(outfile, moke_us_path, moke_us)
return
def txfr_flow_day(nodes_to_txfr_day):
""" Unsmoothed transfer from CALSIM file to model input file.
"""
calsimfile = getAttr("CALSIMFILE")
f = opendss(calsimfile) # open CALSIM file
outfile = getAttr("BOUNDARYFILE")
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
tw = prepro_window()
for calsimname in nodes_to_txfr_day: # Extend the list as needed
mf = calsim_study_fpart(modify=1)
dsspath = calsim_path(calsimname)
dsspath1 = calsim_path(calsimname, modified_fpart=mf)
processedpath = dsspath1.replace("1MON", "1DAY")
print dsspath
print processedpath
paths = findpath(f, dsspath)
if not paths or len(paths) > 1:
print "File: %s" % calsimfile
raise "Path %s not found or not unique" % dsspath
ref = DataReference.create(paths[0], tw)
monthly = ref.getData()
daily = interpolate(monthly, "1DAY")
if daily:
writedss(outfile, processedpath, daily)
else:
raise "Failure to find CALSIM input data for: " + calsimname
def transfer_flow(nodes_to_transfer):
""" Unsmoothed transfer from CALSIM file to model input file.
"""
calsimfile = getAttr("CALSIMFILE")
f = opendss(calsimfile) # open CALSIM file
outfile = getAttr("BOUNDARYFILE")
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
tw = prepro_window()
for calsimname in nodes_to_transfer: # Extend the list as needed, but please keep in mind the
# limitations of the conservative spline, at least at present.
# Mainly, input flows should be substantially greater than
# zero at all times (yolo would be inappropriate, for instance)
dsspath = calsim_path(calsimname)
paths = findpath(f, dsspath)
if not paths or len(paths) > 1:
print "File: %s" % calsimfile
raise "Path %s not found or not unique" % dsspath
ref = DataReference.create(paths[0], tw)
monthly = ref.getData()
mf = calsim_study_fpart(modify=1)
dsspath = calsim_path(calsimname, modified_fpart=mf)
if monthly:
writedss(outfile, dsspath, monthly)
else:
raise "Failure to find CALSIM input data for: " + calsimname
def extend_flow(nodes_to_extend):
""" Copying WY1922 data to WY1921 for allowing to preprocessing and running DSM2
from 01Jan1921.
"""
calsimfile=getAttr("CALSIMFILE")
f=opendss(calsimfile) # open CALSIM file
outfile=getAttr("BOUNDARYFILE")
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
tw=timewindow("01OCT1921 0000 - 01OCT1922 0000")
for calsimname in nodes_to_extend:
print calsimname
dsspath = calsim_path(calsimname)
paths = findpath(f,dsspath)
if not paths or len(paths)>1:
print "File: %s" % calsimfile
raise "Path %s not found or not unique" % dsspath
ref=DataReference.create(paths[0],tw)
monthly=ref.getData()
itr = monthly.getIterator()
d=zeros(len(monthly),'d')
count=0
while not itr.atEnd():
el = itr.getElement()
d[count] = el.getY()
count = count + 1
itr.advance()
stime = "01OCT1920 0000"
rts = RegularTimeSeries(monthly.getName(),stime, \
timeinterval("1MON").toString(), d, None, monthly.getAttributes())
writedss(calsimfile,ref.getPathname().toString(),rts)
def prep_vamp_ndo(calsimfile, outdss, fpart):
STEP = string.lower(config.getAttr('CALSIMSTEP'))
# CALSIM=opendss(calsimfile)
SJR_PROCESS = config.getAttr("SJR_PROCESS")
startyr = int(config.getAttr('START_DATE')[5:])
endyr = int(config.getAttr('END_DATE')[5:])
if (startyr < 1974 and endyr > 1991):
twstr = "01NOV1921 0000 - 01OCT2003 0000"
else:
twstr = "01OCT1974 0000 - 01OCT1991 0000"
path = "/CALSIM/NDO/FLOW-NDO//" + STEP + "/" + fpart + "/"
ndo = dss_retrieve_ts(calsimfile, path, twstr)
print ndo
ndo15 = conserve.conserveSpline(ndo, "15MIN")
if (SJR_PROCESS.upper() == "SINGLE_STEP") or (SJR_PROCESS.upper()
== "MULTI_STEP"):
fpart_modified = calsim_study_fpart(modify=1)
delta_ndo = calc_vamp_delta_ndo(calsimfile, outdss, fpart,
fpart_modified, SJR_PROCESS)
ndo15_vamp = ndo15 + interpolate(delta_ndo, "15MIN")
writedss(calsimfile, "/CALSIM/NDO/FLOW-NDO//15MIN/" + fpart + "/",
ndo15_vamp)
def moke_consumnes():
calsimfile = getAttr("CALSIMFILE")
f = opendss(calsimfile) # open CALSIM file
outfile = getAttr("BOUNDARYFILE")
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
tw = prepro_window()
moke_us_path = calsim_path("I504")
moke_ref = findpath(f, moke_us_path)
if moke_ref and len(moke_ref) > 0:
print "Upstream mokelumne flow found, not calculated"
consumnes_path = calsim_path("C501")
moke_ds_path = calsim_path("C504")
consumnes_ref = findpath(f, consumnes_path)
if not consumnes_ref:
raise "Consumnes path %s not found" % consumnes_path
moke_ds_ref = findpath(f, moke_ds_path)
if not moke_ds_ref:
raise "Mokulemne downstream path %s not found" % moke_ds_path
consumnes = DataReference.create(consumnes_ref[0], tw).getData()
moke_ds = DataReference.create(moke_ds_ref[0], tw).getData()
mf = calsim_study_fpart(modify=1)
moke_us_path = calsim_path("I504", mf)
moke_us = moke_ds - consumnes
writedss(outfile, moke_us_path, moke_us)
return
def transfer_ec():
""" Unsmoothed transfer from CALSIM file to model input file.
"""
f=opendss(getAttr("CALSIMFILE")) # open CALSIM file
outfile=getAttr("BOUNDARYFILE")
process=getAttr("SJR_PROCESS")
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
tw=prepro_window()
calsimstudy=calsim_study_fpart(modify=0)
calsimstudyout=calsim_study_fpart(modify=1)
if not calsimstudy or calsimstudy=="":
print "CALSIMSTUDY envvar not set"
dsspath="/CALSIM.*/VERNWQFINAL/SALINITY-EC//1MON/%s/" % calsimstudy
processedpath=dsspath.replace(".*","-"+process).replace(
"1MON","1DAY").replace(calsimstudy,calsimstudyout)
print processedpath
refs=findpath(f,dsspath)
if not refs or len(refs)> 1:
raise "Vernalis EC path %s not found or not unique" % dsspath
ref=DataReference.create(refs[0],tw)
monthly=ref.getData()
daily=interpolate(monthly,"1DAY")
if daily:
writedss(outfile,processedpath, daily)
else:
raise "Failure to find CALSIM input data for: " + calsimname
return
def txfr_flow_day(nodes_to_txfr_day):
""" Unsmoothed transfer from CALSIM file to model input file.
"""
calsimfile = getAttr("CALSIMFILE")
f = opendss(calsimfile) # open CALSIM file
outfile = getAttr("BOUNDARYFILE")
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
tw = prepro_window()
for calsimname in nodes_to_txfr_day: # Extend the list as needed
mf = calsim_study_fpart(modify=1)
dsspath = calsim_path(calsimname)
dsspath1 = calsim_path(calsimname, modified_fpart=mf)
processedpath = dsspath1.replace("1MON", "1DAY")
print dsspath
print processedpath
paths = findpath(f, dsspath)
if not paths or len(paths) > 1:
print "File: %s" % calsimfile
raise "Path %s not found or not unique" % dsspath
ref = DataReference.create(paths[0], tw)
monthly = ref.getData()
daily = interpolate(monthly, "1DAY")
if daily:
writedss(outfile, processedpath, daily)
else:
raise "Failure to find CALSIM input data for: " + calsimname
def extend_flow(nodes_to_extend):
""" Copying WY1922 data to WY1921 for allowing to preprocessing and running DSM2
from 01Jan1921.
"""
calsimfile = getAttr("CALSIMFILE")
f = opendss(calsimfile) # open CALSIM file
outfile = getAttr("BOUNDARYFILE")
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
tw = timewindow("01OCT1921 0000 - 01OCT1922 0000")
for calsimname in nodes_to_extend:
print calsimname
dsspath = calsim_path(calsimname)
paths = findpath(f, dsspath)
if not paths or len(paths) > 1:
print "File: %s" % calsimfile
raise "Path %s not found or not unique" % dsspath
ref = DataReference.create(paths[0], tw)
monthly = ref.getData()
itr = monthly.getIterator()
d = zeros(len(monthly), 'd')
count = 0
while not itr.atEnd():
el = itr.getElement()
d[count] = el.getY()
count = count + 1
itr.advance()
stime = "01OCT1920 0000"
rts = RegularTimeSeries(monthly.getName(),stime, \
timeinterval("1MON").toString(), d, None, monthly.getAttributes())
writedss(calsimfile, ref.getPathname().toString(), rts)
def dccOp(infile,outfile,inpath,outpath,allThirty=1,value=1.0,
tw="01OCT1974 0000 - 01OCT1991 0000"):
"""
Converts Delta Cross Channel gate operation
from a CALSIM file containing fraction of days open
Args:
infile CALSIM dss file specifying # days operating
outfile output dss file readable by DSM2
inpath input path, e.g. /CALSIM/DXC/GATE-DAYS-OPEN//1MON//
outpath output path, e.g. /CALSIM/DXC/GATE//IR-YEAR/fpart/
value time series value when gate is opened (must be 1.0 or 2.0),
where 1.0 is used for gate ops and 2.0 is number gates operating.
tw time window of output
allThirty true if CALSIM input is hardwired to thirty day months
"""
from vutils import timewindow
from vdss import opendss,findpath,writedss
from vista.time import TimeWindow
from vista.set import DataReference
import types
g=opendss(infile)
if not (type(outfile) == types.StringType):
raise TypeError("Argument outfile should be name of a dss file")
if not isinstance(tw,TimeWindow):
tw = timewindow(tw)
if not (value==1.0 or value==2.0):
raise "Output time series 'on' value should be 1.0 (gate op) or 2.0 (gates operating)"
x=findpath(g,inpath)[0]
dxcref = DataReference.create(findpath(g,inpath)[0],tw)
dxc=dxcref.getData()
if not dxc:
raise "Cross channel data not found"
dxcITS=daysPerMonthToITS(dxc,value,allThirty)
writedss(outfile,outpath,dxcITS)
return dxcITS
def transfer_flow(nodes_to_transfer):
""" Unsmoothed transfer from CALSIM file to model input file.
"""
calsimfile = getAttr("CALSIMFILE")
f = opendss(calsimfile) # open CALSIM file
outfile = getAttr("BOUNDARYFILE")
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
tw = prepro_window()
for calsimname in nodes_to_transfer: # Extend the list as needed, but please keep in mind the
# limitations of the conservative spline, at least at present.
# Mainly, input flows should be substantially greater than
# zero at all times (yolo would be inappropriate, for instance)
dsspath = calsim_path(calsimname)
paths = findpath(f, dsspath)
if not paths or len(paths) > 1:
print "File: %s" % calsimfile
raise "Path %s not found or not unique" % dsspath
ref = DataReference.create(paths[0], tw)
monthly = ref.getData()
mf = calsim_study_fpart(modify=1)
dsspath = calsim_path(calsimname, modified_fpart=mf)
if monthly:
writedss(outfile, dsspath, monthly)
else:
raise "Failure to find CALSIM input data for: " + calsimname
def doall(dicufile, bndryfile):
sum = net_dicu(dicufile, [334, 333, 332, 331, 330])
pathname = sum.getPathname().toString()
pathname = set_part(pathname, 'NET_DICU_NORTH_OF_FREEPORT',
Pathname.B_PART)
pathname = set_part(pathname, 'FLOW', Pathname.C_PART)
writedss(dicufile, pathname, sum.getData())
def doall(dicufile, bndryfile):
sum = net_dicu(dicufile, [335, 336, 337, 338, 339, 340, 341, 342])
pathname = sum.getPathname().toString()
pathname = set_part(pathname, 'NET_DICU_RSAC155_TO_RSAC128',
Pathname.B_PART)
pathname = set_part(pathname, 'FLOW', Pathname.C_PART)
writedss(dicufile, pathname, sum.getData())
def prep_ndo(calsimf, dss_step, dss_fpart, twstr):
ndofile = opendss(calsimf)
TWIND = timewindow(twstr)
ndo = DataReference.create(
findpath(ndofile, "/CALSIM/NDO/FLOW-NDO//" + dss_step + "/" +
dss_fpart + "/")[0], TWIND).getData()
ndo15 = conserve.conserveSpline(ndo, "15MIN")
ndo15.getAttributes().setYUnits("CFS")
ndo15.getAttributes().setYType("PER-AVER")
writedss(calsimf, "/CALSIM/NDO/FLOW-NDO//15MIN/" + dss_fpart + "/", ndo15)
return 0
def compare_dss_files(file1, file2, showPlot=False, outputFile=None, outputPathFile=None):
"""
Simply compares the files and outputs differences if any of those that differ and lists mismatching pathnames in either
"""
g1 = vutils.opendss(file1)
g2 = vutils.opendss(file2)
print 'Comparing %s to %s' % (file1, file2)
print '%12s\t%32s' % ('DIFFERENCE', 'PATHNAME')
if outputPathFile:
opf_handle=open(outputPathFile, 'wb')
opf = csv.writer(opf_handle, delimiter=",", quotechar='"', quoting=csv.QUOTE_MINIMAL)
opf.writerow([file1,file2])
no_diff=True
for ref1 in g1:
p1 = ref1.pathname
found = False
for ref2 in g2:
p2 = ref2.pathname
if matches(p1, p2):
found = True
diff = ref2.data - ref1.data
absdiff = diff.createSlice(diff.getTimeWindow())
vtimeseries.apply(absdiff, math.fabs)
diff_total = vtimeseries.total(absdiff)
if (diff_total > 1e-06) :
no_diff=False
if showPlot: plot(ref1.data, ref2.data)
print '%10.2f\t%32s' % (diff_total, p1)
if outputFile:
diffp = set_part(p1, 'DIFF-%s-%s' % (os.path.basename(file1), os.path.basename(file2)), Pathname.A_PART)
writedss(outputFile, str(diffp), diff)
if outputPathFile:
opf.writerow([p1, p1, diff_total])
break
if (not found):
no_diff=False
print 'No matching path: %s in file %s NOT found in file %s' % (p1, file1, file2)
if outputPathFile: opf.writerow([p1, "", "M"])
for ref2 in g2:
p2 = ref2.pathname
found = False
for ref1 in g1:
p1 = ref1.pathname
if matches(p1, p2):
found = True
break
if (not found):
no_diff=False
print 'No matching path: %s in file %s NOT found in file %s' % (p2, file2, file1)
if outputPathFile: opf.writerow(["", p2, "M"])
if no_diff:
print 'NO DIFFERENCE ACROSS ENTIRE FILEs %s and %s'%(file1,file2)
if outputPathFile: opf_handle.close()
def prep_dicu(infile,outfile,tw):
from vdss import opendss,writedss,findpath
if (not infile): raise TypeError("infile was None")
if (not outfile): raise TypeError("outfile was None")
if (not infile.endswith("dss") and outfile.endswith("dss")):
raise "infile and outfile arguments must be a dss file"
g=opendss(infile)
all=findpath(g,"///DRAIN-EC////")
for i in range(len(all)):
ts=all[i].getData()
s=expand_seasonal(ts,tw)
writedss(outfile,all[i].getPathname().toString(),s)
def prep_dicu(infile, outfile, tw):
from vdss import opendss, writedss, findpath
if (not infile): raise TypeError("infile was None")
if (not outfile): raise TypeError("outfile was None")
if (not infile.endswith("dss") and outfile.endswith("dss")):
raise "infile and outfile arguments must be a dss file"
g = opendss(infile)
all = findpath(g, "///DRAIN-EC////")
for i in range(len(all)):
ts = all[i].getData()
s = expand_seasonal(ts, tw)
writedss(outfile, all[i].getPathname().toString(), s)
def download_data_in_yearly_chunks(station_name, sensor_number, start_year, end_year, file): """ Downloads data in year long chunks. CDEC cannot handle really large data requests so this is the best way to work around that. It writes the data to file of your choice as opposed to returning a time series. """ for year in range(start_year, end_year): start_date = "01/01/%s"%str(year) end_date="12/31/%s"%(str(year)) rts=retrieve(station_name,sensor_number,start_date,end_date,verbose=1) #if rts: vdisplay.plot(rts) writedss(file,rts.name,rts) #
def copy_dicu_flow():
""" Unsmoothed transfer from DICU file to model input file.
"""
dicufile=getAttr("DICUFLOWFILE")
f=opendss(dicufile) # open CALSIM file
outfile=getAttr("DICUFILE")
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
tw=prepro_window()
for item in f :
ref=DataReference.create(item,tw)
data=ref.getData()
writedss(outfile,ref.getPathname().toString(), data)
def copy_dicu_flow():
""" Unsmoothed transfer from DICU file to model input file.
"""
dicufile=getAttr("DICUFLOWFILE")
f=opendss(dicufile) # open CALSIM file
outfile=getAttr("DICUFILE")
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
tw=prepro_window()
for item in f :
ref=DataReference.create(item,tw)
data=ref.getData()
writedss(outfile,ref.getPathname().toString(), data)
def copy_stage():
""" Unsmoothed transfer from DICU file to model input file.
"""
sourcefile=getAttr("STAGE_SOURCE_FILE")
f=opendss(sourcefile)
outfile=getAttr("STAGEFILE")
stageversion=getAttr("STAGE_VERSION")
dsspath="/FILL\+CHAN/RSAC054/STAGE//15MIN/%s/" % stageversion
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
tw=prepro_window()
ref = findpath(f,dsspath)
if len(ref) != 1:
raise "Stage path not found or not unique. Found refs: %s" % ref
ref=DataReference.create(ref[0],tw)
data=ref.getData()
writedss(outfile,ref.getPathname().toString(), data)
def copy_stage():
""" Unsmoothed transfer from DICU file to model input file.
"""
sourcefile = getAttr("STAGE_SOURCE_FILE")
f = opendss(sourcefile)
outfile = getAttr("STAGEFILE")
stageversion = getAttr("STAGE_VERSION")
dsspath = "/FILL\+CHAN/RSAC054/STAGE//15MIN/%s/" % stageversion
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
tw = prepro_window()
ref = findpath(f, dsspath)
if len(ref) != 1:
raise "Stage path not found or not unique. Found refs: %s" % ref
ref = DataReference.create(ref[0], tw)
data = ref.getData()
writedss(outfile, ref.getPathname().toString(), data)
def smooth_flow(nodes_to_smooth):
""" A slightly smoothed version of monthly flows to avoid sharp transitions
between months. Uses a tension spline.
"""
calsimfile=getAttr("CALSIMFILE")
f=opendss(calsimfile) # open CALSIM file
outfile=getAttr("BOUNDARYFILE")
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
fpart_mod=calsim_study_fpart(modify=1)
tw=prepro_window()
for calsimname in nodes_to_smooth: # Extend the list as needed, but please keep in mind the
# limitations of the conservative spline, at least at present.
# Mainly, input flows should be substantially greater than
# zero at all times (yolo would be inappropriate, for instance)
dsspath = calsim_path(calsimname)
paths=findpath(f,dsspath)
if not paths or len(paths)>1:
print "File: %s" % calsimfile
raise "Path %s not found or not unique" % dsspath
ref=DataReference.create(paths[0],tw)
monthly=ref.getData()
if monthly:
if len(monthly) < 4:
raise "Length of monthly data too short for smoothing. Wrong time window?"
try:
daily=conserve.conserveSpline(monthly,"1DAY")
except:
print "Failure to smooth path: %s over time window: %s" % (paths[0], tw)
raise
daily.getAttributes().setYUnits(Units.CFS)
writedss(outfile,
"/CALSIM-SMOOTH/"+calsimname+"/FLOW/1DAY//" \
+fpart_mod+"/",
daily)
else:
raise "Failure to find CALSIM input data for: " + calsimname
def smooth_flow(nodes_to_smooth):
""" A slightly smoothed version of monthly flows to avoid sharp transitions
between months. Uses a tension spline.
"""
calsimfile = getAttr("CALSIMFILE")
f = opendss(calsimfile) # open CALSIM file
outfile = getAttr("BOUNDARYFILE")
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
fpart_mod = calsim_study_fpart(modify=1)
tw = prepro_window()
for calsimname in nodes_to_smooth: # Extend the list as needed, but please keep in mind the
# limitations of the conservative spline, at least at present.
# Mainly, input flows should be substantially greater than
# zero at all times (yolo would be inappropriate, for instance)
dsspath = calsim_path(calsimname)
paths = findpath(f, dsspath)
if not paths or len(paths) > 1:
print "File: %s" % calsimfile
raise "Path %s not found or not unique" % dsspath
ref = DataReference.create(paths[0], tw)
monthly = ref.getData()
if monthly:
if len(monthly) < 4:
raise "Length of monthly data too short for smoothing. Wrong time window?"
try:
daily = conserve.conserveSpline(monthly, "1DAY")
except:
print "Failure to smooth path: %s over time window: %s" % (
paths[0], tw)
raise
daily.getAttributes().setYUnits(Units.CFS)
writedss(outfile,
"/CALSIM-SMOOTH/"+calsimname+"/FLOW/1DAY//" \
+fpart_mod+"/",
daily)
else:
raise "Failure to find CALSIM input data for: " + calsimname
def dccOp(infile,
outfile,
inpath,
outpath,
allThirty=1,
value=1.0,
tw="01OCT1974 0000 - 01OCT1991 0000"):
"""
Converts Delta Cross Channel gate operation
from a CALSIM file containing fraction of days open
Args:
infile CALSIM dss file specifying # days operating
outfile output dss file readable by DSM2
inpath input path, e.g. /CALSIM/DXC/GATE-DAYS-OPEN//1MON//
outpath output path, e.g. /CALSIM/DXC/GATE//IR-YEAR/fpart/
value time series value when gate is opened (must be 1.0 or 2.0),
where 1.0 is used for gate ops and 2.0 is number gates operating.
tw time window of output
allThirty true if CALSIM input is hardwired to thirty day months
"""
from vutils import timewindow
from vdss import opendss, findpath, writedss
from vista.time import TimeWindow
from vista.set import DataReference
import types
g = opendss(infile)
if not (type(outfile) == types.StringType):
raise TypeError("Argument outfile should be name of a dss file")
if not isinstance(tw, TimeWindow):
tw = timewindow(tw)
if not (value == 1.0 or value == 2.0):
raise "Output time series 'on' value should be 1.0 (gate op) or 2.0 (gates operating)"
x = findpath(g, inpath)[0]
dxcref = DataReference.create(findpath(g, inpath)[0], tw)
dxc = dxcref.getData()
if not dxc:
raise "Cross channel data not found"
dxcITS = daysPerMonthToITS(dxc, value, allThirty)
writedss(outfile, outpath, dxcITS)
return dxcITS
def calaveras():
calsimfile = getAttr("CALSIMFILE")
f = opendss(calsimfile) # open CALSIM file
outfile = getAttr("BOUNDARYFILE")
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
tw = prepro_window()
cal_path = calsim_path("C508")
cal_ret_path = calsim_path("R514")
cal_ref = findpath(f, cal_path)
if not cal_ref:
raise "Calaveras path %s not found" % cal_path
cal_ret_ref = findpath(f, cal_ret_path)
if not cal_ret_ref:
raise "Calaveras return flow path %s not found" % cal_ret_path
cal = DataReference.create(cal_ref[0], tw).getData()
cal_ret = DataReference.create(cal_ret_ref[0], tw).getData()
mf = calsim_study_fpart(modify=1)
cal_in_path = calsim_path("C508_R514", mf)
cal_in = cal + cal_ret
writedss(outfile, cal_in_path, cal_in)
return
def calaveras():
calsimfile = getAttr("CALSIMFILE")
f = opendss(calsimfile) # open CALSIM file
outfile = getAttr("BOUNDARYFILE")
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
tw = prepro_window()
cal_path = calsim_path("C508")
cal_ret_path = calsim_path("R514")
cal_ref = findpath(f, cal_path)
if not cal_ref:
raise "Calaveras path %s not found" % cal_path
cal_ret_ref = findpath(f, cal_ret_path)
if not cal_ret_ref:
raise "Calaveras return flow path %s not found" % cal_ret_path
cal = DataReference.create(cal_ref[0], tw).getData()
cal_ret = DataReference.create(cal_ret_ref[0], tw).getData()
mf = calsim_study_fpart(modify=1)
cal_in_path = calsim_path("C508_R514", mf)
cal_in = cal + cal_ret
writedss(outfile, cal_in_path, cal_in)
return
def project_export_limits(pulse_limit, ei_ratio,delta_inflow):
"""Refine export limits to include EI ratio and allocate
limits to CVP and SWP.
Arguments:
pulse_limit: the raw combined export limit from CALSIM
ei_ratio: the maximum E/I ratio calculated by CALSIM
delta_inflow: total inflow to the delta calculated by CALSIM
Output:
swp_limit,cvp_limit: Maximum pumping allowed during VAMP for
each of the individual projects. This routine
calculates maximum pumping, not actual pumping
"""
if ei_ratio.getStartTime() != pulse_limit.getStartTime():
raise ValueError("EI limit and total export limit must have same start time")
# Limit pulse according to EI ratio
eilimit=ei_ratio*delta_inflow
# Now apply export limit. in the CALSIM file the limit probably
# will have values only for APR and MAY, whereas the ei limit
# exists every month
tsmonth=month_numbers(pulse_limit)
is_april_may=(tsmonth==4)+(tsmonth==5)
limit=ts_where(is_april_may *(pulse_limit < eilimit) > 0.,
pulse_limit,
eilimit)
if DEBUG:
writedss("out","/CALC/LIM/////",limit)
# Try to allocate to cvp and swp equally. CVP has a
# mimimum pumping level of 800cfs in which case SWP takes the rest
even_allocation=limit/2.
# trick that converts scalar cvp min to time series with same start, interval
cvp_min_pump=even_allocation*0. + CVP_MIN_PUMP
# forget about cavitation limit in the (fix CALSIM!!) case where
# the cavitation minimum is less than total pumping limit for both
# projects combined -- instead use the total pumping limit
cvp_min_pump=ts_where(cvp_min_pump > limit, limit, cvp_min_pump)
cvp_limit=ts_where(even_allocation > cvp_min_pump,
even_allocation,
cvp_min_pump)
swp_limit=limit-cvp_limit
if DEBUG:
writedss("out","/CALC/EVENALLOC/////",even_allocation)
writedss("out","/CALC/CVPLIM/////",cvp_limit)
writedss("out","/CALC/SWPLIM/////",swp_limit)
writedss("out","/CALC/PULSELIM/////",pulse_limit)
writedss("out","/CALC/EILIM/////",eilimit)
return swp_limit,cvp_limit
import sys
print "IN prep DOC"
infile = sys.argv[1]
config.setConfigVars(infile)
tw = prepro_window()
print "Expanding seasonal DICU DOC drainage values"
expand_seasonal_bst.prep_dicu(
config.getAttr('DICUFILE_DOC'), # original DICU DSS file for EC
config.getAttr(
'DICUFILE_DOCE'
), # processed DICU DSS file (will be input for DSM2)
"DRAIN-DOC",
tw)
print "Expanding seasonal boundary DOC values"
# expand_seasonal_bst.prep_dicu(
# config.getAttr('TSFILE_DOC'), # original DICU DSS file for EC
# config.getAttr('DICUFILE_DOCE'), # processed DICU DSS file (will be input for DSM2)
# "DOC",tw)
f = opendss(config.getAttr("TSFILE_DOC")) # open DOC boundary file
outfile = config.getAttr("BOUNDARYFILE")
f2 = find(f, 'DOC', 'c')
for ref in f2:
path = ref.getPathname()
daily = vutils.interpolate(ref.getData(), "1DAY")
path.setPart(Pathname.E_PART, '1DAY')
path.setPart(Pathname.F_PART, config.getAttr('DSM2MODIFIER'))
mod_path = path.toString()
writedss(outfile, mod_path, daily)
sys.exit()
def planning_ec_mtz(): # MTZ = RSAC054 BC for the qual
DEBUG = 0
OUTPUT=config.getAttr('QUALBOUNDARYFILE')
calsimfile = config.getAttr('CALSIMFILE')
vamp_corrected_dss = config.getAttr('CALSIM_VAMP')
CALSIM=opendss(calsimfile)
PLANNINGTIDE=opendss(config.getAttr('STAGE_SOURCE_FILE'))
STEP=string.lower(config.getAttr('CALSIMSTEP'))
SJR_PROCESS=config.getAttr("SJR_PROCESS")
outputpath="/FILL+CHAN/RSAC054/EC//15MIN/"+config.getAttr("DSM2MODIFIER")+"/"
if not(OUTPUT and os.path.exists(OUTPUT)):
raise "Envvar QUALBOUNDARYFILE must exist as destination for EC"
startyr=int(config.getAttr('START_DATE')[5:])
endyr=int(config.getAttr('END_DATE')[5:])
if (startyr < 1974 and endyr > 1991):
# blocks= [ "01NOV1921 0000 - 01OCT1940 0000",
blocks= [ "01FEB1921 0000 - 01OCT1940 0000",
"01OCT1940 0000 - 01OCT1960 0000",
"01OCT1960 0000 - 01OCT1974 0000",
"01OCT1974 0000 - 01OCT1991 0000",
"01OCT1991 0000 - 01OCT2003 0000"
]
else:
blocks = [ "01OCT1974 0000 - 01OCT1991 0000" ]
# for memory reasons (year 2001).
g0=5000. # initial value of g (antecedent outflow) for the beginning
# of the first year. This is pretty arbitrary and makes little difference
if DEBUG:
g0_no_vamp = 5000.
for twstr in blocks:
TWIND=timewindow(twstr) # Actual period to be estimated
print "Calculating boundary salinity for the period "+TWIND.toString()
TWINDBUF=grow_window(TWIND,"1MON","1MON") # Conservative buffered period for retrieval
# so that after prelimiary operations (e.g. time average)
# time series will still span at least TWIND
fpart=calsim_study_fpart(modify=0)
ndo=DataReference.create(findpath(CALSIM,"/CALSIM/NDO/FLOW-NDO//"+STEP+"/"
+fpart+"/")[0],TWIND).getData()
ndo15=conserve.conserveSpline(ndo,"15MIN")
ndo15_no_vamp = 0
if DEBUG:
ndo15_no_vamp = ndo15
# removed since currently there is no difference between vamp and monthly average.
# calc vamp caused ndo change
# if (SJR_PROCESS.upper()=="SINGLE_STEP") or (SJR_PROCESS.upper()=="MULTI_STEP"):
# fpart_modified=calsim_study_fpart(modify=1)
# delta_ndo = vamp_ndo.calc_vamp_delta_ndo(calsimfile,vamp_corrected_dss,fpart,fpart_modified,SJR_PROCESS)
# ndo15 = ndo15 + interpolate(delta_ndo, "15MIN")
astro_stage_version = config.getAttr("ASTRO_STAGE_VERSION")
mtzastro=DataReference.create(findpath(PLANNINGTIDE,"/FILL\+CHAN/RSAC054/STAGE//15MIN/"+astro_stage_version + "/")[0],TWINDBUF).getData()
astrorms=godin((mtzastro*mtzastro)**0.5) # RMS energy of tide (used to predict filling and draining)
dastrorms=( (astrorms-(astrorms>>1))*96. ).createSlice(TWIND)
fifteenflo2=ndo15 - 40000*(dastrorms)
# call to ec estimator. all parameters are included. g0 is an
[mtzecest, g1]=ec_boundary.ECEst(mtzastro,fifteenflo2,beta=600,npow1=0.75,npow2=1,g0=g0,zrms=astrorms)
if DEBUG:
fifteenflo2_no_vamp = ndo15_no_vamp - 40000*(dastrorms)
[mtzecest_no_vamp, g1_no_vamp]=ec_boundary.ECEst(mtzastro,fifteenflo2_no_vamp,beta=600,npow1=0.75,npow2=1,g0=g0_no_vamp,zrms=astrorms)
g0_no_vamp = g1_no_vamp
writedss("out_ec_check","/CALC/ndo_no_vamp/ndo////", ndo15_no_vamp)
writedss("out_ec_check","/CALC/ndo_with_vamp/ndo////", ndo15)
writedss("out_ec_check","/CALC/ndo_no_vamp/ec////", mtzecest_no_vamp)
writedss("out_ec_check","/CALC/ndo_with_vamp/ec////", mtzecest)
writedss(OUTPUT,outputpath,mtzecest)
g0=g1
return 0
else:
print "IN prep DOC"
infile = sys.argv[1]
config.setConfigVars(infile)
tw=prepro_window()
print "Expanding seasonal DICU DOC drainage values"
expand_seasonal_bst.prep_dicu(
config.getAttr('DICUFILE_DOC'), # original DICU DSS file for EC
config.getAttr('DICUFILE_DOCE'), # processed DICU DSS file (will be input for DSM2)
"DRAIN-DOC",tw)
print "Expanding seasonal boundary DOC values"
# expand_seasonal_bst.prep_dicu(
# config.getAttr('TSFILE_DOC'), # original DICU DSS file for EC
# config.getAttr('DICUFILE_DOCE'), # processed DICU DSS file (will be input for DSM2)
# "DOC",tw)
f=opendss(config.getAttr("TSFILE_DOC")) # open DOC boundary file
outfile=config.getAttr("BOUNDARYFILE")
f2=find(f,'DOC','c')
for ref in f2:
path = ref.getPathname()
daily = vutils.interpolate(ref.getData(),"1DAY")
path.setPart(Pathname.E_PART, '1DAY')
path.setPart(Pathname.F_PART, config.getAttr('DSM2MODIFIER'))
mod_path = path.toString()
writedss(outfile, mod_path, daily)
sys.exit()
def dss_store_ts(file, path, ts):
writedss(file, path, ts)
def compare_dss_files(file1,
file2,
showPlot=False,
outputFile=None,
outputPathFile=None):
"""
Simply compares the files and outputs differences if any of those that differ and lists mismatching pathnames in either
"""
g1 = vutils.opendss(file1)
g2 = vutils.opendss(file2)
print 'Comparing %s to %s' % (file1, file2)
print '%12s\t%32s' % ('DIFFERENCE', 'PATHNAME')
if outputPathFile:
opf_handle = open(outputPathFile, 'wb')
opf = csv.writer(opf_handle,
delimiter=",",
quotechar='"',
quoting=csv.QUOTE_MINIMAL)
opf.writerow([file1, file2])
no_diff = True
for ref1 in g1:
p1 = ref1.pathname
found = False
for ref2 in g2:
p2 = ref2.pathname
if matches(p1, p2):
found = True
diff = ref2.data - ref1.data
absdiff = diff.createSlice(diff.getTimeWindow())
vtimeseries.apply(absdiff, math.fabs)
diff_total = vtimeseries.total(absdiff)
if (diff_total > 1e-06):
no_diff = False
if showPlot: plot(ref1.data, ref2.data)
print '%10.2f\t%32s' % (diff_total, p1)
if outputFile:
diffp = set_part(
p1, 'DIFF-%s-%s' %
(os.path.basename(file1), os.path.basename(file2)),
Pathname.A_PART)
writedss(outputFile, str(diffp), diff)
if outputPathFile:
opf.writerow([p1, p1, diff_total])
break
if (not found):
no_diff = False
print 'No matching path: %s in file %s NOT found in file %s' % (
p1, file1, file2)
if outputPathFile: opf.writerow([p1, "", "M"])
for ref2 in g2:
p2 = ref2.pathname
found = False
for ref1 in g1:
p1 = ref1.pathname
if matches(p1, p2):
found = True
break
if (not found):
no_diff = False
print 'No matching path: %s in file %s NOT found in file %s' % (
p2, file2, file1)
if outputPathFile: opf.writerow(["", p2, "M"])
if no_diff:
print 'NO DIFFERENCE ACROSS ENTIRE FILEs %s and %s' % (file1, file2)
if outputPathFile: opf_handle.close()
def doall(dicufile,bndryfile):
sum=net_dicu(dicufile,[335,336,337,338,339,340,341,342])
pathname=sum.getPathname().toString()
pathname=set_part(pathname,'NET_DICU_RSAC155_TO_RSAC128',Pathname.B_PART)
pathname=set_part(pathname,'FLOW',Pathname.C_PART)
writedss(dicufile,pathname,sum.getData())
config_file=sys.argv[1]
from ConfigParser import ConfigParser
config=ConfigParser()
config.read(config_file)
tidefile=config.get('default','tidefile')
cranges_raw=config.get('default','channel_ranges')
try:
twstr=config.get('default','timewindow');
except:
twstr=None
try:
reservoir_names=config.get('default','reservoir_names')
reservoir_names=string.split(reservoir_names,',')
except:
reservoir_names=None
print 'Calculating volume from tidefile: %s'%tidefile
print 'Channel ranges: %s'+cranges_raw
#channel_ranges=[(54,105),(183,203),(125,145),(204,225),(217,231),(233,235),(252,257)]
#channel_ranges=[(54,82),(84,105),(183,203),(125,145),(204,214),(216,231),(233,235),(252,259)]
channel_ranges=eval(cranges_raw)
volumes=get_volumes_data(tidefile, channel_ranges, twstr)
if reservoir_names != None:
reservoir_volumes=get_reservoir_volumes_data(tidefile,reservoir_names,twstr)
volumes.extend(reservoir_volumes)
total_volume=total(volumes)
outdssfile=config.get('default','output_dss_file')
outdsspath=config.get('default','output_dss_path')
print 'Writing out to %s as %s'%(outdssfile,outdsspath)
writedss(outdssfile,outdsspath,total_volume)
exit(0)
#
def project_export_limits(pulse_limit, ei_ratio, delta_inflow):
"""Refine export limits to include EI ratio and allocate
limits to CVP and SWP.
Arguments:
pulse_limit: the raw combined export limit from CALSIM
ei_ratio: the maximum E/I ratio calculated by CALSIM
delta_inflow: total inflow to the delta calculated by CALSIM
Output:
swp_limit,cvp_limit: Maximum pumping allowed during VAMP for
each of the individual projects. This routine
calculates maximum pumping, not actual pumping
"""
if ei_ratio.getStartTime() != pulse_limit.getStartTime():
raise ValueError(
"EI limit and total export limit must have same start time")
# Limit pulse according to EI ratio
eilimit = ei_ratio * delta_inflow
# Now apply export limit. in the CALSIM file the limit probably
# will have values only for APR and MAY, whereas the ei limit
# exists every month
tsmonth = month_numbers(pulse_limit)
is_april_may = (tsmonth == 4) + (tsmonth == 5)
limit = ts_where(is_april_may * (pulse_limit < eilimit) > 0., pulse_limit,
eilimit)
if DEBUG:
writedss("out", "/CALC/LIM/////", limit)
# Try to allocate to cvp and swp equally. CVP has a
# mimimum pumping level of 800cfs in which case SWP takes the rest
even_allocation = limit / 2.
# trick that converts scalar cvp min to time series with same start, interval
cvp_min_pump = even_allocation * 0. + CVP_MIN_PUMP
# forget about cavitation limit in the (fix CALSIM!!) case where
# the cavitation minimum is less than total pumping limit for both
# projects combined -- instead use the total pumping limit
cvp_min_pump = ts_where(cvp_min_pump > limit, limit, cvp_min_pump)
cvp_limit = ts_where(even_allocation > cvp_min_pump, even_allocation,
cvp_min_pump)
swp_limit = limit - cvp_limit
if DEBUG:
writedss("out", "/CALC/EVENALLOC/////", even_allocation)
writedss("out", "/CALC/CVPLIM/////", cvp_limit)
writedss("out", "/CALC/SWPLIM/////", swp_limit)
writedss("out", "/CALC/PULSELIM/////", pulse_limit)
writedss("out", "/CALC/EILIM/////", eilimit)
return swp_limit, cvp_limit
def calculate_exports(limit, average_value):
"""Determines pulse and non-pulse export flows
for cvp or swp given the refined limits on the
export and the average for one of the projects.
This routine assures that the limit is
only used if it will reduce pumping
and that the pulse and non-pulse flows combine to
give the correct total monthly average pumping.
Arguments:
limit: time series of (refined) limits
on exports for the project
(cvp or swp) being analyzed.
average_value: time series of monthly average pumping
for the project
Output:
export_value: Time series of actual exports.
"""
total_time_in_month,pulse_time_in_month,non_pulse_time_in_month = \
calculate_vamp_times(limit)
# Calculate a volumetrically correct non-pulse flow given that average_value gives
# the total volume of pumping for the month and that pulse pumping is at the limit
limit_volume = limit * pulse_time_in_month
total_volume = average_value * total_time_in_month
non_pulse_volume = total_volume - limit_volume
non_pulse_flow = non_pulse_volume / non_pulse_time_in_month
volume_corrected_limit = replace_vamp(
limit, # replace shoulder first
non_pulse_flow,
include_shoulder=1)
volume_corrected_limit = replace_vamp(
volume_corrected_limit, #now correct pulse period
limit,
include_shoulder=0)
# Create an indicator time series to show months where the pulse pumping
# limit is greater than average (the pulse pumping limit should be a curtailment).
# Note that this is converted to daily by "spreading it out" over the days, but it
# is an indicator of a monthly condition and every day has the same value.
limit_exceeds_average = limit > average_value
limit_exceeds_average = interpolate(limit_exceeds_average, '1DAY')
average_value = interpolate(average_value, '1DAY')
# Now use average_value for months where the pulse limit would lead to an increase
# and the volume-corrected pulse/non-pulse combination otherwise.
export_value = ts_where(limit_exceeds_average, average_value,
volume_corrected_limit)
if (DEBUG):
writedss("out.dss", "/EXP/CVP/EXPORT////", export_value)
writedss("out.dss", "/EXP/CVP/VCL////", volume_corrected_limit)
writedss("out.dss", "/EXP/CVP/NONPULSE////",
interpolate(non_pulse_flow, '1DAY'))
writedss("out.dss", "/EXP/CVP/AVE////", average_value)
writedss("out.dss", "/EXP/CVP/LIM////", interpolate(limit, '1DAY'))
writedss("out.dss", "/EXP/CVP/LIM_EXCEED_AVE////",
limit_exceeds_average)
export_value.getAttributes().setYUnits("CFS")
export_value.getAttributes().setYType("PER-AVER")
return export_value
line = fh.readline()
while not line.startswith("DATE"):
line = fh.readline()
line = fh.readline()
line = fh.readline()
tf = TimeFactory.getInstance()
timeinterval = "IR-DAY"
vals = []
tvals = []
ncount = 0
while line != None or line.strip() != "":
fields = line.split()
if len(fields) < 4:
print "No data in line #%d: %s" % (ncount, line)
break
else:
date, time = fields[0:2]
vtime = tf.createTime(date + " " + time, "MM/dd/yyyy HH:mm:ss")
tvals.append(vtime.create(vtime))
vals.append(float(fields[3]))
ncount = ncount + 1
line = fh.readline()
fh.close()
attr = DataSetAttr(DataType.IRREGULAR_TIME_SERIES, "", "UMHOS/CM", "TIME", "INST-VAL")
return IrregularTimeSeries("TIME SERIES", tvals, vals, None, attr)
if __name__ == "__main__":
ts = read_ts("d:/data/usgs_ec/11455780.uv.95.lower.rdb")
writedss("D:/data/usgs_ec/USGS_ECstations.dss", "/USGS/BENICIA/EC//IR-DAY/11455780-lower/", ts)
else:
tw = prepro_window("16yr")
tws = str(tw)
print "Using time window: %s (dcc processing may exceed your run dates)" % tws
dcc.dccOp(
getAttr('CALSIMFILE'), # CALSIM DSS file (input for DSM2)
getAttr('GATEFILE'), # processed gate DSS file (will be input for DSM2)
'/CALSIM/DXC/GATE-DAYS-OPEN//1MON//' + getAttr('CALSIMSTUDY') + '/', # CALSIM DXC pathname
'/CALSIM-PROCESSED/DCC/OP//IR-YEAR/' + \
getAttr('CALSIMSTUDY') + '/', # processed cross channel pathname
0, # 0: CALSIM input is hardwired to 30-day months
1, # operate gate between 0 & 1
tws # time window
)
print 'Copying gate ops for Clifton Court'
path='/PLANNING\+GATE/CHWST000/OP-FROM-NODE//IR-YEAR/%s/' \
% getAttr("CLIFTONCT_GATEOP")
f=vdss.opendss(getAttr('CLIFTONCT_GATEFILE'))
g=vdss.findpath(f,path)
if ( not g or len(g) != 1):
raise "Path not found or not unique: %s" % (path)
ts=DataReference.create(g[0]).getData()
vdss.writedss(getAttr('GATEFILE'),path.replace("\\",""),ts)
print "Finished with clifton court transfer"
sys.exit(0)
#
def calculate_exports(limit,average_value):
"""Determines pulse and non-pulse export flows
for cvp or swp given the refined limits on the
export and the average for one of the projects.
This routine assures that the limit is
only used if it will reduce pumping
and that the pulse and non-pulse flows combine to
give the correct total monthly average pumping.
Arguments:
limit: time series of (refined) limits
on exports for the project
(cvp or swp) being analyzed.
average_value: time series of monthly average pumping
for the project
Output:
export_value: Time series of actual exports.
"""
total_time_in_month,pulse_time_in_month,non_pulse_time_in_month = \
calculate_vamp_times(limit)
# Calculate a volumetrically correct non-pulse flow given that average_value gives
# the total volume of pumping for the month and that pulse pumping is at the limit
limit_volume=limit*pulse_time_in_month
total_volume = average_value*total_time_in_month
non_pulse_volume = total_volume - limit_volume
non_pulse_flow=non_pulse_volume/non_pulse_time_in_month
volume_corrected_limit = replace_vamp(limit, # replace shoulder first
non_pulse_flow,
include_shoulder=1)
volume_corrected_limit=replace_vamp(volume_corrected_limit, #now correct pulse period
limit,
include_shoulder=0)
# Create an indicator time series to show months where the pulse pumping
# limit is greater than average (the pulse pumping limit should be a curtailment).
# Note that this is converted to daily by "spreading it out" over the days, but it
# is an indicator of a monthly condition and every day has the same value.
limit_exceeds_average = limit > average_value
limit_exceeds_average=interpolate(limit_exceeds_average,'1DAY')
average_value=interpolate(average_value,'1DAY')
# Now use average_value for months where the pulse limit would lead to an increase
# and the volume-corrected pulse/non-pulse combination otherwise.
export_value = ts_where(limit_exceeds_average,average_value, volume_corrected_limit)
if (DEBUG):
writedss("out.dss","/EXP/CVP/EXPORT////",export_value)
writedss("out.dss","/EXP/CVP/VCL////",volume_corrected_limit)
writedss("out.dss","/EXP/CVP/NONPULSE////",interpolate(non_pulse_flow,'1DAY'))
writedss("out.dss","/EXP/CVP/AVE////",average_value)
writedss("out.dss","/EXP/CVP/LIM////",interpolate(limit,'1DAY'))
writedss("out.dss","/EXP/CVP/LIM_EXCEED_AVE////",limit_exceeds_average)
export_value.getAttributes().setYUnits("CFS")
export_value.getAttributes().setYType("PER-AVER")
return export_value
def dss_store_ts(file,path,ts):
writedss(file,path,ts)
if int(sdate[5:]) < 1974:
tw = prepro_window("82yr")
else:
tw = prepro_window("16yr")
tws = str(tw)
print "Using time window: %s (dcc processing may exceed your run dates)" % tws
dcc.dccOp(
getAttr('CALSIMFILE'), # CALSIM DSS file (input for DSM2)
getAttr('GATEFILE'), # processed gate DSS file (will be input for DSM2)
'/CALSIM/DXC/GATE-DAYS-OPEN//1MON//' + getAttr('CALSIMSTUDY') + '/', # CALSIM DXC pathname
'/CALSIM-PROCESSED/DCC/OP//IR-YEAR/' + \
getAttr('CALSIMSTUDY') + '/', # processed cross channel pathname
0, # 0: CALSIM input is hardwired to 30-day months
1, # operate gate between 0 & 1
tws # time window
)
print 'Copying gate ops for Clifton Court'
path='/PLANNING\+GATE/CHWST000/OP-FROM-NODE//IR-YEAR/%s/' \
% getAttr("CLIFTONCT_GATEOP")
f = vdss.opendss(getAttr('CLIFTONCT_GATEFILE'))
g = vdss.findpath(f, path)
if (not g or len(g) != 1):
raise "Path not found or not unique: %s" % (path)
ts = DataReference.create(g[0]).getData()
vdss.writedss(getAttr('GATEFILE'), path.replace("\\", ""), ts)
print "Finished with clifton court transfer"
sys.exit(0)
#
def smooth_flow2():
""" A slightly smoothed version of monthly flows to avoid sharp transitions
between months. Uses a tension spline.
"""
calsimfile = getAttr("CALSIMFILE")
f = opendss(calsimfile) # open CALSIM file
outfile = getAttr("BOUNDARYFILE")
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
fpart_mod = calsim_study_fpart(modify=1)
tw = prepro_window()
print "Preparing SAC and SJR Inflows"
sjr_path = calsim_path("C639")
sjr_ret_path = calsim_path("R644")
sjr_ref = findpath(f, sjr_path)
if not sjr_ref:
raise "San Joaquin path %s not found" % sjr_path
sjr_ret_ref = findpath(f, sjr_ret_path)
if not sjr_ret_ref:
raise "San Joaquin return flow path %s not found" % sjr_ret_path
sjr = DataReference.create(sjr_ref[0], tw) # .getData()
sjr_ret = DataReference.create(sjr_ret_ref[0], tw) # .getData()
sjr_in = sjr + sjr_ret
sac_path = calsim_path("C169")
frwa_div1_path = calsim_path("D168B")
frwa_div2_path = calsim_path("D168C")
sac_ref = findpath(f, sac_path)
if not sac_ref:
raise "Sacramento path %s not found" % sac_path
frwa_div1_ref = findpath(f, frwa_div1_path)
if not frwa_div1_ref:
raise "Freeport Regional Water Authority Diversion path %s not found" % frwa_div1_path
frwa_div2_ref = findpath(f, frwa_div2_path)
if not frwa_div2_ref:
raise "Freeport Regional Water Authority Diversion path %s not found" % frwa_div2_path
sac = DataReference.create(sac_ref[0], tw) # .getData()
frwa_div1 = DataReference.create(frwa_div1_ref[0], tw) # .getData()
frwa_div2 = DataReference.create(frwa_div2_ref[0], tw) # .getData()
sac_in = sac + frwa_div1 + frwa_div2
# sjr_sac(sjr_inf,sac_inf)
print "smoothing SAC"
sac_mon = sac_in.getData()
if sac_mon:
if len(sac_mon) < 4:
raise "Length of monthly data too short for smoothing. Wrong time window?"
try:
sac_day = conserve.conserveSpline(sac_mon, "1DAY")
except:
print "Failure to smooth path: %s over time window: %s" % ("C169_D168B_D168C", tw)
raise
sac_day.getAttributes().setYUnits(Units.CFS)
writedss(outfile, "/CALSIM-SMOOTH/C169_D168B_D168C/FLOW/1DAY//" + fpart_mod + "/", sac_day)
else:
raise "Failure to find monthly data for C169+D168B+D168C"
print "smoothing SJR"
sjr_mon = sjr_in.getData()
if sjr_mon:
if len(sjr_mon) < 4:
raise "Length of monthly data too short for smoothing. Wrong time window?"
try:
sjr_day = conserve.conserveSpline(sjr_mon, "1DAY")
except:
print "Failure to smooth path: %s over time window: %s" % ("C639_R644", tw)
raise
sjr_day.getAttributes().setYUnits(Units.CFS)
writedss(outfile, "/CALSIM-SMOOTH/C639_R644/FLOW/1DAY//" + fpart_mod + "/", sjr_day)
else:
raise "Failure to find monthly data for C639+R644"
def planning_ec_mtz(): # MTZ = RSAC054 BC for the qual
DEBUG = 0
OUTPUT=config.getAttr('QUALBOUNDARYFILE')
calsimfile = config.getAttr('CALSIMFILE')
vamp_corrected_dss = config.getAttr('CALSIM_VAMP')
CALSIM=opendss(calsimfile)
PLANNINGTIDE=opendss(config.getAttr('STAGE_SOURCE_FILE'))
STEP=string.lower(config.getAttr('CALSIMSTEP'))
SJR_PROCESS=config.getAttr("SJR_PROCESS")
outputpath="/FILL+CHAN/RSAC054/EC//15MIN/"+config.getAttr("DSM2MODIFIER")+"/"
if not(OUTPUT and os.path.exists(OUTPUT)):
raise "Envvar QUALBOUNDARYFILE must exist as destination for EC"
startyr=int(config.getAttr('START_DATE')[5:])
endyr=int(config.getAttr('END_DATE')[5:])
if (startyr < 1974 and endyr > 1991):
blocks= [ "01NOV1921 0000 - 01OCT1940 0000",
"01OCT1940 0000 - 01OCT1960 0000",
"01OCT1960 0000 - 01OCT1974 0000",
"01OCT1974 0000 - 01OCT1991 0000",
"01OCT1991 0000 - 01OCT2003 0000"
]
else:
blocks = [ "01OCT1974 0000 - 01OCT1991 0000" ]
# for memory reasons (year 2001).
g0=5000. # initial value of g (antecedent outflow) for the beginning
# of the first year. This is pretty arbitrary and makes little difference
if DEBUG:
g0_no_vamp = 5000.
for twstr in blocks:
TWIND=timewindow(twstr) # Actual period to be estimated
print "Calculating boundary salinity for the period "+TWIND.toString()
TWINDBUF=grow_window(TWIND,"1MON","1MON") # Conservative buffered period for retrieval
# so that after prelimiary operations (e.g. time average)
# time series will still span at least TWIND
fpart=calsim_study_fpart(modify=0)
ndo=DataReference.create(findpath(CALSIM,"/CALSIM/NDO/FLOW-NDO//"+STEP+"/"
+fpart+"/")[0],TWIND).getData()
ndo15=conserve.conserveSpline(ndo,"15MIN")
ndo15_no_vamp = 0
if DEBUG:
ndo15_no_vamp = ndo15
# calc vamp caused ndo change
if (SJR_PROCESS.upper()=="SINGLE_STEP") or (SJR_PROCESS.upper()=="MULTI_STEP"):
fpart_modified=calsim_study_fpart(modify=1)
delta_ndo = vamp_ndo.calc_vamp_delta_ndo(calsimfile,vamp_corrected_dss,fpart,fpart_modified,SJR_PROCESS)
ndo15 = ndo15 + interpolate(delta_ndo, "15MIN")
astro_stage_version = config.getAttr("ASTRO_STAGE_VERSION")
mtzastro=DataReference.create(findpath(PLANNINGTIDE,"/FILL\+CHAN/RSAC054/STAGE//15MIN/"+astro_stage_version + "/")[0],TWINDBUF).getData()
astrorms=godin((mtzastro*mtzastro)**0.5) # RMS energy of tide (used to predict filling and draining)
dastrorms=( (astrorms-(astrorms>>1))*96. ).createSlice(TWIND)
fifteenflo2=ndo15 - 40000*(dastrorms)
# call to ec estimator. all parameters are included. g0 is an
[mtzecest, g1]=ec_boundary.ECEst(mtzastro,fifteenflo2,beta=600,npow1=0.75,npow2=1,g0=g0,zrms=astrorms)
if DEBUG:
fifteenflo2_no_vamp = ndo15_no_vamp - 40000*(dastrorms)
[mtzecest_no_vamp, g1_no_vamp]=ec_boundary.ECEst(mtzastro,fifteenflo2_no_vamp,beta=600,npow1=0.75,npow2=1,g0=g0_no_vamp,zrms=astrorms)
g0_no_vamp = g1_no_vamp
writedss("out_ec_check","/CALC/ndo_no_vamp/ndo////", ndo15_no_vamp)
writedss("out_ec_check","/CALC/ndo_with_vamp/ndo////", ndo15)
writedss("out_ec_check","/CALC/ndo_no_vamp/ec////", mtzecest_no_vamp)
writedss("out_ec_check","/CALC/ndo_with_vamp/ec////", mtzecest)
writedss(OUTPUT,outputpath,mtzecest)
g0=g1
return 0
import sys import config import time import jarray,math import vutils from vista.time import TimeFactory, TimeInterval,Time from vista.set import DataReference, Units, Pathname from vdss import opendss,findpath,writedss,find from vtimeseries import timewindow,timeinterval from config import getAttr,setConfigVars from calsim_study_fpart import calsim_study_fpart from planning_time_window import prepro_window from jarray import zeros,array from vista.set import RegularTimeSeries,DataSetAttr,DataType,Constants from vdisplay import plot,tabulate from vmath import per_avg, per_max, mov_avg, godin, per_min from vutils import Constants, RegularTimeSeries from transfer import transfer configfile = sys.argv[1] # configuration file param = sys.argv[2] # param is the second argument and can be "VOL_FP","EC_FP","200nodes_FP" sind = int(sys.argv[3]) # start index of DSS Records eind = int(sys.argv[4]) # end index of DSS Records setConfigVars(configfile) DSSENVVAR = "QUAL_OUTDSS_%s" % param infile = getAttr(DSSENVVAR) g = opendss(infile) outfile = "%s_PostPro.DSS"% infile[:-4] print "Processing Results for..." for n in range(sind-1,eind,1): ref = g[n]
from ConfigParser import ConfigParser
config = ConfigParser()
config.read(config_file)
tidefile = config.get('default', 'tidefile')
cranges_raw = config.get('default', 'channel_ranges')
try:
twstr = config.get('default', 'timewindow')
except:
twstr = None
try:
reservoir_names = config.get('default', 'reservoir_names')
reservoir_names = string.split(reservoir_names, ',')
except:
reservoir_names = None
print 'Calculating volume from tidefile: %s' % tidefile
print 'Channel ranges: %s' + cranges_raw
#channel_ranges=[(54,105),(183,203),(125,145),(204,225),(217,231),(233,235),(252,257)]
#channel_ranges=[(54,82),(84,105),(183,203),(125,145),(204,214),(216,231),(233,235),(252,259)]
channel_ranges = eval(cranges_raw)
volumes = get_volumes_data(tidefile, channel_ranges, twstr)
if reservoir_names != None:
reservoir_volumes = get_reservoir_volumes_data(tidefile,
reservoir_names, twstr)
volumes.extend(reservoir_volumes)
total_volume = total(volumes)
outdssfile = config.get('default', 'output_dss_file')
outdsspath = config.get('default', 'output_dss_path')
print 'Writing out to %s as %s' % (outdssfile, outdsspath)
writedss(outdssfile, outdsspath, total_volume)
exit(0)
#
def smooth_flow2():
""" A slightly smoothed version of monthly flows to avoid sharp transitions
between months. Uses a tension spline.
"""
calsimfile = getAttr("CALSIMFILE")
f = opendss(calsimfile) # open CALSIM file
outfile = getAttr("BOUNDARYFILE")
if not outfile or outfile == "":
raise "Config variable BOUNDARYFILE not set and needed for prepro output"
fpart_mod = calsim_study_fpart(modify=1)
tw = prepro_window()
print "Preparing SAC and SJR Inflows"
sjr_path = calsim_path("C639")
sjr_ret_path = calsim_path("R644")
sjr_ref = findpath(f, sjr_path)
if not sjr_ref:
raise "San Joaquin path %s not found" % sjr_path
sjr_ret_ref = findpath(f, sjr_ret_path)
if not sjr_ret_ref:
raise "San Joaquin return flow path %s not found" % sjr_ret_path
sjr = DataReference.create(sjr_ref[0], tw) #.getData()
sjr_ret = DataReference.create(sjr_ret_ref[0], tw) #.getData()
sjr_in = sjr + sjr_ret
sac_path = calsim_path("C169")
frwa_div1_path = calsim_path("D168B")
frwa_div2_path = calsim_path("D168C")
sac_ref = findpath(f, sac_path)
if not sac_ref:
raise "Sacramento path %s not found" % sac_path
frwa_div1_ref = findpath(f, frwa_div1_path)
if not frwa_div1_ref:
raise "Freeport Regional Water Authority Diversion path %s not found" % frwa_div1_path
frwa_div2_ref = findpath(f, frwa_div2_path)
if not frwa_div2_ref:
raise "Freeport Regional Water Authority Diversion path %s not found" % frwa_div2_path
sac = DataReference.create(sac_ref[0], tw) #.getData()
frwa_div1 = DataReference.create(frwa_div1_ref[0], tw) #.getData()
frwa_div2 = DataReference.create(frwa_div2_ref[0], tw) #.getData()
sac_in = sac + frwa_div1 + frwa_div2
# sjr_sac(sjr_inf,sac_inf)
print "smoothing SAC"
sac_mon = sac_in.getData()
if sac_mon:
if len(sac_mon) < 4:
raise "Length of monthly data too short for smoothing. Wrong time window?"
try:
sac_day = conserve.conserveSpline(sac_mon, "1DAY")
except:
print "Failure to smooth path: %s over time window: %s" % (
"C169_D168B_D168C", tw)
raise
sac_day.getAttributes().setYUnits(Units.CFS)
writedss(outfile,
"/CALSIM-SMOOTH/C169_D168B_D168C/FLOW/1DAY//" \
+fpart_mod+"/",sac_day)
else:
raise "Failure to find monthly data for C169+D168B+D168C"
print "smoothing SJR"
sjr_mon = sjr_in.getData()
if sjr_mon:
if len(sjr_mon) < 4:
raise "Length of monthly data too short for smoothing. Wrong time window?"
try:
sjr_day = conserve.conserveSpline(sjr_mon, "1DAY")
except:
print "Failure to smooth path: %s over time window: %s" % (
"C639_R644", tw)
raise
sjr_day.getAttributes().setYUnits(Units.CFS)
writedss(outfile,
"/CALSIM-SMOOTH/C639_R644/FLOW/1DAY//" \
+fpart_mod+"/",sjr_day)
else:
raise "Failure to find monthly data for C639+R644"
def planning_ec_mtz(): # MTZ = RSAC054 BC for the qual
DEBUG = 0
OUTPUT = config.getAttr('QUALBOUNDARYFILE')
calsimfile = config.getAttr('CALSIMFILE')
CALSIM = opendss(calsimfile)
PLANNINGTIDE = opendss(config.getAttr('STAGE_SOURCE_FILE'))
outputpath = "/FILL+CHAN/RSAC054/EC//15MIN/" + config.getAttr(
"DSM2MODIFIER") + "/"
if not (OUTPUT and os.path.exists(OUTPUT)):
raise "Envvar QUALBOUNDARYFILE must exist as destination for EC"
startyr = int(config.getAttr('START_DATE')[5:])
endyr = int(config.getAttr('END_DATE')[5:])
if (startyr < 1974 and endyr > 1991):
blocks = [
"01NOV1921 0000 - 01OCT1940 0000",
"01OCT1940 0000 - 01OCT1960 0000",
"01OCT1960 0000 - 01OCT1974 0000",
"01OCT1974 0000 - 01OCT1991 0000",
"01OCT1991 0000 - 01OCT2003 0000"
] # for memory reasons (year 2001).
else:
blocks = ["01OCT1974 0000 - 01OCT1991 0000"]
g0 = 5000. # initial value of g (antecedent outflow) for the beginning
# of the first year. This is pretty arbitrary and makes little difference
for twstr in blocks:
TWIND = timewindow(twstr) # Actual period to be estimated
print "Calculating boundary salinity for the period " + TWIND.toString(
)
TWINDBUF = grow_window(
TWIND, "1MON",
"1MON") # Conservative buffered period for retrieval
# so that after prelimiary operations (e.g. time average)
# time series will still span at least TWIND
fpart = calsim_study_fpart(modify=0)
ndo15 = DataReference.create(
findpath(CALSIM, "/CALSIM/NDO/FLOW-NDO//15MIN/" + fpart + "/")[0],
TWIND).getData()
astro_stage_version = config.getAttr("ASTRO_STAGE_VERSION")
mtzastro = DataReference.create(
findpath(
PLANNINGTIDE, "/FILL\+CHAN/RSAC054/STAGE//15MIN/" +
astro_stage_version + "/")[0], TWINDBUF).getData()
if 'NAVD' in astro_stage_version:
mtzastro = mtzastro - 2.68
writedss(
CALSIM, "/FILL\+CHAN/RSAC054/STAGE//15MIN/" +
astro_stage_version.replace('NAVD', 'NGVD') + "/", mtzastro)
astrorms = godin(
(mtzastro * mtzastro)**
0.5) # RMS energy of tide (used to predict filling and draining)
dastrorms = ((astrorms - (astrorms >> 1)) * 96.).createSlice(TWIND)
fifteenflo2 = ndo15 - 53411.1 * (dastrorms)
# call to ec estimator. all parameters are included.
so, sb = 37196, 2328.1
c = [
-6.00E-05, 7.30E-05, -1.00E-05, -3.00E-05, 1.70E-06, -1.00E-04,
4.50E-05, -1.00E-04
]
[mtzecest, g1] = ec_boundary.ECEst(mtzastro,
fifteenflo2,
so,
sb,
beta=420.5205,
npow1=0.7750588,
npow2=1,
g0=g0,
zrms=astrorms,
c=c)
writedss(OUTPUT, outputpath, mtzecest)
g0 = g1
return 0
def doall(dicufile,bndryfile):
sum=net_dicu(dicufile,[334,333,332,331,330])
pathname=sum.getPathname().toString()
pathname=set_part(pathname,'NET_DICU_NORTH_OF_FREEPORT',Pathname.B_PART)
pathname=set_part(pathname,'FLOW',Pathname.C_PART)
writedss(dicufile,pathname,sum.getData())
import sys
import config
import time
import jarray, math
import vutils
from vista.time import TimeFactory, TimeInterval, Time
from vista.set import DataReference, Units, Pathname
from vdss import opendss, findpath, writedss, find
from vtimeseries import timewindow, timeinterval
from config import getAttr, setConfigVars
from calsim_study_fpart import calsim_study_fpart
from planning_time_window import prepro_window
from jarray import zeros, array
from vista.set import RegularTimeSeries, DataSetAttr, DataType, Constants
from vdisplay import plot, tabulate
from vmath import per_avg, per_max, mov_avg, godin, per_min
from vutils import Constants, RegularTimeSeries
from transfer import transfer
configfile = sys.argv[1] # configuration file
param = sys.argv[
2] # param is the second argument and can be "VOL_FP","EC_FP","200nodes_FP"
sind = int(sys.argv[3]) # start index of DSS Records
eind = int(sys.argv[4]) # end index of DSS Records
setConfigVars(configfile)
DSSENVVAR = "QUAL_OUTDSS_%s" % param
infile = getAttr(DSSENVVAR)
g = opendss(infile)
outfile = "%s_PostPro.DSS" % infile[:-4]
print "Processing Results for..."
for n in range(sind - 1, eind, 1):
