Finding Intersections with Python: Difference between revisions
Brian Wilson (talk | contribs) |
Brian Wilson (talk | contribs) |
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To accomplish this I am reading '''Python Geospatial Development''' by Erik Westra. Packt Pubs | To accomplish this I am reading '''Python Geospatial Development''' by Erik Westra. Packt Pubs | ||
I've been working a lot with PostGIS lately and it would be ideal for this project. HOWEVER I need to be able to give it to some ESRI users and | |||
I | I don't want to teach them how to use PostGIS as part of that project. This means I will be using Shapely. | ||
I want to be able to use File Geodatabases, so I will be using a custom built GDAL with Python bindings. | I want to be able to use File Geodatabases, so I will be using a custom built GDAL with Python bindings on Linux | ||
and the OSGeo4W version on Windows. | |||
=== GDAL === | === GDAL === | ||
Here is a page where I talk about [[Building GDAL on Linux]]. | Here is a page where I talk about [[Building GDAL on Linux]]. | ||
I guess I should also do a write up on [[Using OSGeo4W]] but I have not done that yet. | |||
=== Shapely === | === Shapely === | ||
Line 54: | Line 56: | ||
With the tools at our disposal, this should be ''so easy!'' | With the tools at our disposal, this should be ''so easy!'' | ||
It turns out that ''it is!''. | |||
I was able to write a script in Python and develop it on a '''Linux''' system, and the first time I ran it on '''Windows''', it ran successfully to completion with NO CHANGES. ''Awesome'' | |||
The next part now will be getting it to [[Running GDAL scripts in ESRI Model Builder|run in ESRI Model Builder]]. | |||
Explore data from command line using ogrinfo. | Explore data from command line using ogrinfo. | ||
Line 62: | Line 67: | ||
''Gives lots of info I won't include here'' | ''Gives lots of info I won't include here'' | ||
=== Read shapes into Shapely geometries === | |||
Time to code up some python. I want to be able to read ESRI File Geodatabases too. And write them. | |||
<pre> | <pre> | ||
class InputFeatures: | |||
# Input fields | |||
input_fieldname = "FULLNAME" | |||
# Stubby little streets less than this are ignored. | |||
MinLineLength = 3.0 | |||
FeatureList = [] # tuple containing (hashed name, ogr feature, shapely geom) | |||
SpatialReference = None | |||
BadNameCount = 0 | |||
EmptyNameCount = 0 | |||
BadGeometryCount = 0 | |||
DebugFeatureCount = 0 # Set to some value to load a few features only -- good for testing | |||
_d_ignored_names = {} # ALLEY, UNKNOWN... | |||
def __init__(self, input_fieldname, ignored_path, st_types_path): | |||
self.input_fieldname = input_fieldname | |||
icount = self._load_ignored_names(ignored_path) | |||
if icount == 0: | |||
print "Could not load ignored names file '%s'" % ignored_path | |||
self.condenser = streetnames.Condense() | |||
ccount = self.condenser.LoadStreetTypes(st_types_path) | |||
if ccount == 0: | |||
print "Could not load street types file '%s'" % st_types_path | |||
return | |||
##### | |||
def LoadFeatures(self, fcname): | |||
""" Load everything from the input feature layer into memory. | |||
Well.. not EVERYTHING. Ignores meaningless features. """ | |||
feature_count = 0 | |||
(ogr_ds, ogr_layer) = self._open_layer(fcname) | |||
if not ogr_layer: | |||
print "Can't open input layer '%s'" % fcname | |||
else: | |||
feature_count = self._loadFeatures(ogr_layer) | |||
self.SpatialReference = ogr_layer.GetSpatialRef() | |||
ogr_ds.Destroy() | |||
return feature_count | |||
def _open_layer(self, fcname): | |||
(workspacename, layername) = fc_to_ogrname(fcname) | |||
ds = None | |||
layer = None | |||
try: | |||
ogr.RegisterAll() | |||
ds = ogr.Open(workspacename); | |||
layer = None | |||
if ds: | |||
layer = ds.GetLayerByName(layername) | |||
except Exception: | |||
print "Could not open input feature class '%s" % fcname | |||
return (ds, layer) | |||
def _loadFeatures(self, layer): | |||
max_feature_count = layer.GetFeatureCount() | |||
debug_count = self.DebugFeatureCount | |||
if (debug_count > 0) and (debug_count < max_feature_count): | |||
max_feature_count = debug_count | |||
for i in range(max_feature_count): | |||
if progress and not i % 1000: print i, "..", | |||
feature = layer.GetFeature(i) | |||
if not feature: | |||
self.BadGeometryCount += 1 | |||
continue | |||
name = feature.GetField(self.input_fieldname) | |||
if not name: | |||
self.EmptyNameCount += 1 | |||
continue | |||
# Ignore all streets with names like ALLEY and UNKNOWN | |||
if self._d_ignored_names.has_key(name): | |||
self._d_ignored_names[name] += 1 # count each one to help debugging | |||
self.BadNameCount += 1; | |||
continue | |||
try: | |||
# Convert OGR geometry to Shapely geometry | |||
geometry = feature.GetGeometryRef() | |||
shgeom = shapely.wkt.loads(geometry.ExportToWkt()) | |||
except: | |||
print "%d : %s (EXCEPTION)" % (i, name) | |||
self.BadGeometryCount += 1 | |||
continue | |||
msg = self._featureIsValid(shgeom) | |||
if msg : | |||
print "%d : %s : %s" % (i, name, msg) | |||
self.BadGeometryCount += 1 | |||
continue | |||
# Geometry is good and name is good, so add it to our list | |||
# Make a condensed name from the FULLNAME field. | |||
# I wonder what would happen if I actually used hash() here | |||
hashed = self.condenser.HashStreetName(name) | |||
self.FeatureList.append( (hashed, feature, shgeom) ) | |||
return len(self.FeatureList) | |||
def _featureIsValid(self, shgeom): | |||
""" Return True if this feature passes validity tests. """ | |||
if not shgeom.is_valid: | |||
return "Geometry is not valid." | |||
if shgeom.is_empty: | |||
return "Geometry is empty." | |||
mp = list(shgeom.boundary.geoms) | |||
if len(mp) == 0: | |||
return "Geometry is empty!" | |||
if shgeom.length < self.MinLineLength: | |||
return "Short line ignored." | |||
return None | |||
def isshapefilename(fcname): | |||
if fcname[-4:].lower() == '.shp': | |||
return True | |||
return False | |||
def fc_to_ogrname(fcname): | |||
""" Convert an ESRI feature class name into an OGR workspace and layername """ | |||
try: | |||
if isshapefilename(fcname): | |||
# We're working with a shapefile. | |||
# Don't test for existence because we might be making a new shapefile. | |||
workspacename = fcname | |||
layername = os.path.basename(fcname)[:-4] | |||
return (workspacename, layername) | |||
except Exception: | |||
pass | |||
try: | |||
directory = os.path.dirname(fcname) | |||
if directory[-4:].lower() == '.gdb': | |||
# We're working with a file geodatabase | |||
if not os.path.exists(directory): | |||
print "File geodatabase '%s' does not exist" % directory | |||
return (None, None) | |||
workspacename = directory | |||
layername = os.path.basename(fcname) | |||
return (workspacename, layername) | |||
except Exception: | |||
pass | |||
print "Something is wrong with feature class '%s'" % fcname | |||
return (None,None) | |||
</pre> | |||
=== 2. Use Shapely to find the intersections. === | |||
First I find where lines cross. | |||
Then I look at the endpoints of each line segment. | |||
<pre> | |||
class GenerateCrossPoints: | |||
# Units depend on projection of data source, usually in feet. | |||
BufferDistance = 3.0 | |||
# Trim pre-directionals from output street names when set true | |||
trim_predirectionals = True | |||
# Input | |||
input_fieldname = "FULLNAME" | |||
featureList = None | |||
# Dictionaries for fast look up tables. | |||
d_street_types = {} # ST AV BLVD | |||
d_street_translations = {} # stuff like first => 1 | |||
# OUTPUT | |||
# Has to be a list because of dupe names + modifier (1st and MAIN 1, 1st and MAIN 2,...) | |||
IntersectionList = [] # Tuple (geom, (hash1, hash2), fename1, fename2, modifer, rating) | |||
ErrorList = [] # Tuple (geom, fename1, fename2, errdesc) | |||
# used to differentiate between intersections with same name | |||
_d_modifier = {} # [hashed names] => counter count instances of each name | |||
# rating, lower is better | |||
# 0 = vertex at line crossing | |||
# 1 = endpoint touches a vertex | |||
# 2 = crossing | |||
# 3 = endpoint touches a line | |||
# 4 = line is near vertex | |||
# 5 = endpoint is near a line | |||
# Regular expressions, compiled ahead of need | |||
# Used for trimming predirectionals | |||
re_predir = re.compile(r'^(N|S|W|W|NE|NW|SE|SW)\s(.*)$', re.IGNORECASE) | |||
##################################################### | |||
def __init__(self, input_fieldname): | |||
self.input_fieldname = input_fieldname | |||
pass | |||
######### | |||
def FindIntersections(self, featureList): | |||
self.featureList = featureList | |||
self._findLineIntersections() # where lines cross | |||
self._findEndpointIntersections() # where endpoints meet at vertices | |||
return | |||
def _getVertices(self, geom, points): | |||
""" Given a shapely geometry (line or multi) | |||
Return a list of the points in that object """ | |||
if geom.type == "MultiLineString": | |||
for line in geom.geoms: | |||
self._getVertices(line, points) | |||
else: | |||
for p in geom.coords: | |||
points.append(shapely.geometry.Point(p)) | |||
return | |||
def _adjustName(self, name): | |||
""" Adjust the fename according to trim flag. """ | |||
if self.trim_predirectionals: | |||
mo = self.re_predir.search(name) | |||
if mo: | |||
return mo.group(2) | |||
return name | |||
def _proximate(self, keytuple, pt): | |||
""" Return True if the named pt is close to an existing intersection with the same name. """ | |||
for (ex_pt, ex_keytuple, ex_fename1, ex_fename2, modifier, rating) in self.IntersectionList: | |||
if keytuple == ex_keytuple: | |||
# Has same name, is it nearby? | |||
buffered = pt.buffer(self.BufferDistance) | |||
if ex_pt.within(buffered): | |||
if verbose: | |||
print "Nearby + same name = ignored '%s x %s'" % keytuple | |||
return True | |||
return False | |||
def _add_intersection(self, pt, keytuple, fename1, fename2, rating): | |||
""" Given geometry for a point, condensed name pair, full name pair, and rating, | |||
check to see if this is already in our list of intersections | |||
if not, then add it. """ | |||
# Don't add if it already exists | |||
# 1ST x MAIN | |||
if (keytuple in self._d_modifier): | |||
if self._proximate(keytuple, pt): return; | |||
swapped = (keytuple[1], keytuple[0]) # MAIN x 1ST | |||
if (swapped in self._d_modifier): | |||
if self._proximate(swapped, pt): return; | |||
#print "Swapping names to remove duplication" | |||
t = fename1 | |||
fename1 = fename2 | |||
fename2 = t | |||
keytuple = swapped | |||
# Is there already an intersection with this name? | |||
if self._d_modifier.has_key(keytuple): | |||
modifier = self._d_modifier[keytuple] | |||
self._d_modifier[keytuple] += 1 | |||
else: | |||
self._d_modifier[keytuple] = 1 | |||
modifier = None | |||
# This should be the only place we need to trim the 2 street names, just before storing them. | |||
self.IntersectionList.append((pt, keytuple, self._adjustName(fename1), self._adjustName(fename2), modifier, rating)) | |||
return | |||
##### | |||
def _findLineIntersections(self): | |||
print "Looking for line intersections" | |||
i = test_count = hit_count = 0 | |||
for (condensedname, feature, shgeom) in self.featureList: | |||
for (othercondensedname, otherfeature, othergeom) in self.featureList: | |||
if progress and not i % 1000: | |||
print i, | |||
if not i % 10000: print | |||
i += 1 | |||
test_count += 1 | |||
if condensedname == othercondensedname: | |||
# no self intersections allowed | |||
continue | |||
if shgeom.intersects(othergeom) : | |||
pt = shgeom.intersection(othergeom) | |||
hit_count += 1 | |||
# two lines cross | |||
rating = 2 | |||
# is there a vertex here? | |||
# or is there a vertex NEAR here? | |||
vertices = [] | |||
self._getVertices(othergeom, vertices) | |||
buffered = shgeom.buffer(self.BufferDistance) | |||
for vertex in vertices: | |||
if shgeom.equals(vertex): | |||
rating = 0 # vertex at line crossing | |||
break | |||
if vertex.within(buffered): | |||
rating = 4 # line is near vertex | |||
break; | |||
fename1 = feature.GetField(self.input_fieldname) | |||
fename2 = otherfeature.GetField(self.input_fieldname) | |||
keytuple = (condensedname, othercondensedname) | |||
self._add_intersection(pt, keytuple, fename1, fename2, rating) | |||
if verbose: print "Hit! '%s x %s'" % keytuple | |||
if progress: print | |||
return hit_count | |||
##### | |||
def _findEndpointIntersections(self): | |||
""" This should be run after generating line intersections. | |||
It checks the endpoints of every line. If there is an intersection | |||
there already, fine. Otherwise see if there is a line nearby and | |||
if so, add it. And endpoint is near but not touching a line. """ | |||
print "Looking at endpoints.." | |||
i = 0 | |||
for (condensedname, feature, geom) in self.featureList: | |||
i += 1 | |||
#if progress: print "Checking endpoints for %s" % (condensedname) | |||
fename1 = feature.GetField(self.input_fieldname) | |||
endpoints = list(geom.boundary.geoms) | |||
self._process_linestring_endpoint(condensedname, fename1, endpoints[0]) | |||
self._process_linestring_endpoint(condensedname, fename1, endpoints[1]) | |||
return | |||
##### | |||
def _process_linestring_endpoint(self, condensedname, fename1, endpoint) : | |||
# If there is already an intersection here, | |||
for (i_point, keytuple, ex_fename1, ex_fename2, modifier, rating) in self.IntersectionList: | |||
if endpoint.equals(i_point): | |||
# We're good already. Not an error | |||
# if verbose: print "Endpoint already matched '%s'" % hashkey | |||
return | |||
# else | |||
# is there a line nearby? | |||
buffered = endpoint.buffer(self.BufferDistance) | |||
test_count = hit_count = 0 | |||
for (othercondensedname, otherfeature, othergeom) in self.featureList: | |||
test_count += 1 | |||
if condensedname == othercondensedname: | |||
# no self intersection allowed | |||
pass | |||
# Are we touching | |||
elif endpoint.intersects(othergeom) : | |||
wkt = shapely.wkt.dumps(endpoint) | |||
hit_count += 1 | |||
fename2 = otherfeature.GetField(self.input_fieldname) | |||
rating = 3 # endpoint actually touches a line | |||
keytuple = (condensedname, othercondensedname) | |||
self._add_intersection(endpoint, keytuple, fename1, fename2, rating) | |||
if verbose: print "Endpoint touches line '%s x %s'" % keytuple | |||
# Are we not quite touching | |||
elif buffered.intersects(othergeom) : | |||
wkt = shapely.wkt.dumps(endpoint) | |||
hit_count += 1 | |||
fename2 = otherfeature.GetField(self.input_fieldname) | |||
rating = 5 # endpoint is near a line | |||
keytuple = (condensedname, othercondensedname) | |||
self._add_intersection(endpoint, keytuple, fename1, fename2, rating) | |||
if verbose: print "Endpoint near line '%s x %s'" % keytuple | |||
return hit_count | |||
# end of class definition | |||
</pre> | </pre> | ||
=== 3. Write intersection points to a feature class === | |||
This code can write to either a shapefile or a geodatabase. It looks at the string you pass in and decides. | |||
I use the ESRI concept of a "feature class" to make it easier to run this script from ESRI Model Builder. | |||
* Shapefiles end in .shp for example "foo/bar/intersections.shp" | |||
* Geodatabases have a layername at the end and a GDB in them, for example "goo/gump/features.gdb/intersections". | |||
<pre> | |||
##### | |||
def createOutputLayer(fcname, sref): | |||
(ogr_ds, ogr_layer) = create_layer(fcname, sref) | |||
# Add the attribute fields | |||
fieldDefn = ogr.FieldDefn(fename1_fieldname, ogr.OFTString); | |||
fieldDefn.SetWidth(40) | |||
ogr_layer.CreateField(fieldDefn) | |||
fieldDefn = ogr.FieldDefn(fename2_fieldname, ogr.OFTString); | |||
fieldDefn.SetWidth(40) | |||
ogr_layer.CreateField(fieldDefn) | |||
fieldDefn = ogr.FieldDefn(modifier_fieldname, ogr.OFTString); | |||
fieldDefn.SetWidth(40) | |||
ogr_layer.CreateField(fieldDefn) | |||
fieldDefn = ogr.FieldDefn(rating_fieldname, ogr.OFTInteger); | |||
ogr_layer.CreateField(fieldDefn) | |||
return (ogr_ds, ogr_layer) | |||
def create_layer(fcname, sref): | |||
""" Create a layer for output """ | |||
(ds_name, layer_name) = fc_to_ogrname(fcname) | |||
if isshapefilename(fcname): | |||
driver = ogr.GetDriverByName("ESRI Shapefile") | |||
if os.path.exists(ds_name): | |||
driver.DeleteDataSource(ds_name) | |||
ogr_ds = driver.CreateDataSource(ds_name) | |||
else: | |||
driver = ogr.GetDriverByName("FileGDB") | |||
if os.path.exists(ds_name): | |||
ogr_ds = driver.Open(ds_name) | |||
rval = ogr_ds.DeleteLayer(layer_name) | |||
else: | |||
ogr_ds = driver.CreateDataSource(ds_name) | |||
if ogr_ds is None: | |||
print "Create layer '%s' failed" % ds_name | |||
return (None, None) | |||
ogr_layer = ogr_ds.CreateLayer(layer_name, sref, ogr.wkbPoint) | |||
fieldDefn = ogr.FieldDefn(ID_FIELDNAME, ogr.OFTInteger) | |||
ogr_layer.CreateField(fieldDefn) | |||
return (ogr_ds, ogr_layer) | |||
def saveIntersections(ogr_layer, intersectionList): | |||
global fename1_fieldname, fename2_fieldname, modifier_fieldname | |||
featureDefn = ogr_layer.GetLayerDefn() | |||
not_a_point = 0 | |||
fid = 0 | |||
for (p, keytuple, fename1, fename2, modifier, rating) in intersectionList: | |||
if p.type == "Point": | |||
wkt = shapely.wkt.dumps(p) | |||
feature = ogr.Feature(featureDefn) | |||
feature.SetGeometry(ogr.CreateGeometryFromWkt(wkt)) | |||
fid += 1 | |||
feature.SetField("id", fid); | |||
feature.SetField(fename1_fieldname, fename1) | |||
feature.SetField(fename2_fieldname, fename2) | |||
feature.SetField(rating_fieldname, rating) | |||
feature.SetField(modifier_fieldname, modifier) | |||
ogr_layer.CreateFeature(feature) | |||
# Now create a second feature with the streetnames reversed. | |||
fid += 1 | |||
feature.SetField("id", fid); | |||
feature.SetField(fename1_fieldname, fename2) | |||
feature.SetField(fename2_fieldname, fename1) | |||
feature.SetField(modifier_fieldname, modifier) | |||
ogr_layer.CreateFeature(feature) | |||
feature.Destroy() | |||
else: | |||
not_a_point += 1 | |||
return fid | |||
</pre> | |||
[[Category:GIS]] | [[Category:GIS]] |
Latest revision as of 17:12, 14 June 2013
Where roads meet
We need to be able to build a table of all the places roads meet.
- This is not a page about the general case of geometric intersections. Road intersections.
- And we don't want to find the places that roads CROSS (over- or under-crossings). Just where they join.
Both of these points are salient because they mean dealing with dirty input data. Always the case.
- Roads should always meet at a vertex
- Roads that meet should always have a common vertex, not just be "close".
- Roads that do not meet (crossings) should NOT meet these conditions.
- Any gaps should indicate no connection.
- Any place roads touch but not at a vertex should indicate a crossing.
But none of this is ever true! Alas, we always get data that looks good on a map but is not routable.
To this end, I want a tool that:
- Generates a point layer of intersections
- Generates a point layer of error cases
The tools
I have a version of this program already written in C# using ArcObjects, and it's a BIG MESS. Worst of all, every time I do a build in a new release of ArcGIS, it breaks!
I want something easy to maintain, easy to update, easy to run, and reasonably fast.
To accomplish this I am reading Python Geospatial Development by Erik Westra. Packt Pubs
I've been working a lot with PostGIS lately and it would be ideal for this project. HOWEVER I need to be able to give it to some ESRI users and I don't want to teach them how to use PostGIS as part of that project. This means I will be using Shapely.
I want to be able to use File Geodatabases, so I will be using a custom built GDAL with Python bindings on Linux and the OSGeo4W version on Windows.
GDAL
Here is a page where I talk about Building GDAL on Linux. I guess I should also do a write up on Using OSGeo4W but I have not done that yet.
Shapely
Here is the home of Shapely, where it is described as "PostGIS-ish operations outside a database context for Pythoneers and Pythonistas." Sounds like what I need.
The steps
Starting off with the simplest version, ignoring all the data cleaning.
- Read centerline data with OGR (part of GDAL).
- Find all the crossings with Shapely.
- Write points with appropriate attributes (FENAME1, FENAME2)
With the tools at our disposal, this should be so easy! It turns out that it is!.
I was able to write a script in Python and develop it on a Linux system, and the first time I ran it on Windows, it ran successfully to completion with NO CHANGES. Awesome
The next part now will be getting it to run in ESRI Model Builder.
Explore data from command line using ogrinfo.
ogrinfo -so cntrline.shp cntrline Gives lots of info I won't include here
Read shapes into Shapely geometries
Time to code up some python. I want to be able to read ESRI File Geodatabases too. And write them.
class InputFeatures: # Input fields input_fieldname = "FULLNAME" # Stubby little streets less than this are ignored. MinLineLength = 3.0 FeatureList = [] # tuple containing (hashed name, ogr feature, shapely geom) SpatialReference = None BadNameCount = 0 EmptyNameCount = 0 BadGeometryCount = 0 DebugFeatureCount = 0 # Set to some value to load a few features only -- good for testing _d_ignored_names = {} # ALLEY, UNKNOWN... def __init__(self, input_fieldname, ignored_path, st_types_path): self.input_fieldname = input_fieldname icount = self._load_ignored_names(ignored_path) if icount == 0: print "Could not load ignored names file '%s'" % ignored_path self.condenser = streetnames.Condense() ccount = self.condenser.LoadStreetTypes(st_types_path) if ccount == 0: print "Could not load street types file '%s'" % st_types_path return ##### def LoadFeatures(self, fcname): """ Load everything from the input feature layer into memory. Well.. not EVERYTHING. Ignores meaningless features. """ feature_count = 0 (ogr_ds, ogr_layer) = self._open_layer(fcname) if not ogr_layer: print "Can't open input layer '%s'" % fcname else: feature_count = self._loadFeatures(ogr_layer) self.SpatialReference = ogr_layer.GetSpatialRef() ogr_ds.Destroy() return feature_count def _open_layer(self, fcname): (workspacename, layername) = fc_to_ogrname(fcname) ds = None layer = None try: ogr.RegisterAll() ds = ogr.Open(workspacename); layer = None if ds: layer = ds.GetLayerByName(layername) except Exception: print "Could not open input feature class '%s" % fcname return (ds, layer) def _loadFeatures(self, layer): max_feature_count = layer.GetFeatureCount() debug_count = self.DebugFeatureCount if (debug_count > 0) and (debug_count < max_feature_count): max_feature_count = debug_count for i in range(max_feature_count): if progress and not i % 1000: print i, "..", feature = layer.GetFeature(i) if not feature: self.BadGeometryCount += 1 continue name = feature.GetField(self.input_fieldname) if not name: self.EmptyNameCount += 1 continue # Ignore all streets with names like ALLEY and UNKNOWN if self._d_ignored_names.has_key(name): self._d_ignored_names[name] += 1 # count each one to help debugging self.BadNameCount += 1; continue try: # Convert OGR geometry to Shapely geometry geometry = feature.GetGeometryRef() shgeom = shapely.wkt.loads(geometry.ExportToWkt()) except: print "%d : %s (EXCEPTION)" % (i, name) self.BadGeometryCount += 1 continue msg = self._featureIsValid(shgeom) if msg : print "%d : %s : %s" % (i, name, msg) self.BadGeometryCount += 1 continue # Geometry is good and name is good, so add it to our list # Make a condensed name from the FULLNAME field. # I wonder what would happen if I actually used hash() here hashed = self.condenser.HashStreetName(name) self.FeatureList.append( (hashed, feature, shgeom) ) return len(self.FeatureList) def _featureIsValid(self, shgeom): """ Return True if this feature passes validity tests. """ if not shgeom.is_valid: return "Geometry is not valid." if shgeom.is_empty: return "Geometry is empty." mp = list(shgeom.boundary.geoms) if len(mp) == 0: return "Geometry is empty!" if shgeom.length < self.MinLineLength: return "Short line ignored." return None def isshapefilename(fcname): if fcname[-4:].lower() == '.shp': return True return False def fc_to_ogrname(fcname): """ Convert an ESRI feature class name into an OGR workspace and layername """ try: if isshapefilename(fcname): # We're working with a shapefile. # Don't test for existence because we might be making a new shapefile. workspacename = fcname layername = os.path.basename(fcname)[:-4] return (workspacename, layername) except Exception: pass try: directory = os.path.dirname(fcname) if directory[-4:].lower() == '.gdb': # We're working with a file geodatabase if not os.path.exists(directory): print "File geodatabase '%s' does not exist" % directory return (None, None) workspacename = directory layername = os.path.basename(fcname) return (workspacename, layername) except Exception: pass print "Something is wrong with feature class '%s'" % fcname return (None,None)
2. Use Shapely to find the intersections.
First I find where lines cross.
Then I look at the endpoints of each line segment.
class GenerateCrossPoints: # Units depend on projection of data source, usually in feet. BufferDistance = 3.0 # Trim pre-directionals from output street names when set true trim_predirectionals = True # Input input_fieldname = "FULLNAME" featureList = None # Dictionaries for fast look up tables. d_street_types = {} # ST AV BLVD d_street_translations = {} # stuff like first => 1 # OUTPUT # Has to be a list because of dupe names + modifier (1st and MAIN 1, 1st and MAIN 2,...) IntersectionList = [] # Tuple (geom, (hash1, hash2), fename1, fename2, modifer, rating) ErrorList = [] # Tuple (geom, fename1, fename2, errdesc) # used to differentiate between intersections with same name _d_modifier = {} # [hashed names] => counter count instances of each name # rating, lower is better # 0 = vertex at line crossing # 1 = endpoint touches a vertex # 2 = crossing # 3 = endpoint touches a line # 4 = line is near vertex # 5 = endpoint is near a line # Regular expressions, compiled ahead of need # Used for trimming predirectionals re_predir = re.compile(r'^(N|S|W|W|NE|NW|SE|SW)\s(.*)$', re.IGNORECASE) ##################################################### def __init__(self, input_fieldname): self.input_fieldname = input_fieldname pass ######### def FindIntersections(self, featureList): self.featureList = featureList self._findLineIntersections() # where lines cross self._findEndpointIntersections() # where endpoints meet at vertices return def _getVertices(self, geom, points): """ Given a shapely geometry (line or multi) Return a list of the points in that object """ if geom.type == "MultiLineString": for line in geom.geoms: self._getVertices(line, points) else: for p in geom.coords: points.append(shapely.geometry.Point(p)) return def _adjustName(self, name): """ Adjust the fename according to trim flag. """ if self.trim_predirectionals: mo = self.re_predir.search(name) if mo: return mo.group(2) return name def _proximate(self, keytuple, pt): """ Return True if the named pt is close to an existing intersection with the same name. """ for (ex_pt, ex_keytuple, ex_fename1, ex_fename2, modifier, rating) in self.IntersectionList: if keytuple == ex_keytuple: # Has same name, is it nearby? buffered = pt.buffer(self.BufferDistance) if ex_pt.within(buffered): if verbose: print "Nearby + same name = ignored '%s x %s'" % keytuple return True return False def _add_intersection(self, pt, keytuple, fename1, fename2, rating): """ Given geometry for a point, condensed name pair, full name pair, and rating, check to see if this is already in our list of intersections if not, then add it. """ # Don't add if it already exists # 1ST x MAIN if (keytuple in self._d_modifier): if self._proximate(keytuple, pt): return; swapped = (keytuple[1], keytuple[0]) # MAIN x 1ST if (swapped in self._d_modifier): if self._proximate(swapped, pt): return; #print "Swapping names to remove duplication" t = fename1 fename1 = fename2 fename2 = t keytuple = swapped # Is there already an intersection with this name? if self._d_modifier.has_key(keytuple): modifier = self._d_modifier[keytuple] self._d_modifier[keytuple] += 1 else: self._d_modifier[keytuple] = 1 modifier = None # This should be the only place we need to trim the 2 street names, just before storing them. self.IntersectionList.append((pt, keytuple, self._adjustName(fename1), self._adjustName(fename2), modifier, rating)) return ##### def _findLineIntersections(self): print "Looking for line intersections" i = test_count = hit_count = 0 for (condensedname, feature, shgeom) in self.featureList: for (othercondensedname, otherfeature, othergeom) in self.featureList: if progress and not i % 1000: print i, if not i % 10000: print i += 1 test_count += 1 if condensedname == othercondensedname: # no self intersections allowed continue if shgeom.intersects(othergeom) : pt = shgeom.intersection(othergeom) hit_count += 1 # two lines cross rating = 2 # is there a vertex here? # or is there a vertex NEAR here? vertices = [] self._getVertices(othergeom, vertices) buffered = shgeom.buffer(self.BufferDistance) for vertex in vertices: if shgeom.equals(vertex): rating = 0 # vertex at line crossing break if vertex.within(buffered): rating = 4 # line is near vertex break; fename1 = feature.GetField(self.input_fieldname) fename2 = otherfeature.GetField(self.input_fieldname) keytuple = (condensedname, othercondensedname) self._add_intersection(pt, keytuple, fename1, fename2, rating) if verbose: print "Hit! '%s x %s'" % keytuple if progress: print return hit_count ##### def _findEndpointIntersections(self): """ This should be run after generating line intersections. It checks the endpoints of every line. If there is an intersection there already, fine. Otherwise see if there is a line nearby and if so, add it. And endpoint is near but not touching a line. """ print "Looking at endpoints.." i = 0 for (condensedname, feature, geom) in self.featureList: i += 1 #if progress: print "Checking endpoints for %s" % (condensedname) fename1 = feature.GetField(self.input_fieldname) endpoints = list(geom.boundary.geoms) self._process_linestring_endpoint(condensedname, fename1, endpoints[0]) self._process_linestring_endpoint(condensedname, fename1, endpoints[1]) return ##### def _process_linestring_endpoint(self, condensedname, fename1, endpoint) : # If there is already an intersection here, for (i_point, keytuple, ex_fename1, ex_fename2, modifier, rating) in self.IntersectionList: if endpoint.equals(i_point): # We're good already. Not an error # if verbose: print "Endpoint already matched '%s'" % hashkey return # else # is there a line nearby? buffered = endpoint.buffer(self.BufferDistance) test_count = hit_count = 0 for (othercondensedname, otherfeature, othergeom) in self.featureList: test_count += 1 if condensedname == othercondensedname: # no self intersection allowed pass # Are we touching elif endpoint.intersects(othergeom) : wkt = shapely.wkt.dumps(endpoint) hit_count += 1 fename2 = otherfeature.GetField(self.input_fieldname) rating = 3 # endpoint actually touches a line keytuple = (condensedname, othercondensedname) self._add_intersection(endpoint, keytuple, fename1, fename2, rating) if verbose: print "Endpoint touches line '%s x %s'" % keytuple # Are we not quite touching elif buffered.intersects(othergeom) : wkt = shapely.wkt.dumps(endpoint) hit_count += 1 fename2 = otherfeature.GetField(self.input_fieldname) rating = 5 # endpoint is near a line keytuple = (condensedname, othercondensedname) self._add_intersection(endpoint, keytuple, fename1, fename2, rating) if verbose: print "Endpoint near line '%s x %s'" % keytuple return hit_count # end of class definition
3. Write intersection points to a feature class
This code can write to either a shapefile or a geodatabase. It looks at the string you pass in and decides. I use the ESRI concept of a "feature class" to make it easier to run this script from ESRI Model Builder.
- Shapefiles end in .shp for example "foo/bar/intersections.shp"
- Geodatabases have a layername at the end and a GDB in them, for example "goo/gump/features.gdb/intersections".
##### def createOutputLayer(fcname, sref): (ogr_ds, ogr_layer) = create_layer(fcname, sref) # Add the attribute fields fieldDefn = ogr.FieldDefn(fename1_fieldname, ogr.OFTString); fieldDefn.SetWidth(40) ogr_layer.CreateField(fieldDefn) fieldDefn = ogr.FieldDefn(fename2_fieldname, ogr.OFTString); fieldDefn.SetWidth(40) ogr_layer.CreateField(fieldDefn) fieldDefn = ogr.FieldDefn(modifier_fieldname, ogr.OFTString); fieldDefn.SetWidth(40) ogr_layer.CreateField(fieldDefn) fieldDefn = ogr.FieldDefn(rating_fieldname, ogr.OFTInteger); ogr_layer.CreateField(fieldDefn) return (ogr_ds, ogr_layer) def create_layer(fcname, sref): """ Create a layer for output """ (ds_name, layer_name) = fc_to_ogrname(fcname) if isshapefilename(fcname): driver = ogr.GetDriverByName("ESRI Shapefile") if os.path.exists(ds_name): driver.DeleteDataSource(ds_name) ogr_ds = driver.CreateDataSource(ds_name) else: driver = ogr.GetDriverByName("FileGDB") if os.path.exists(ds_name): ogr_ds = driver.Open(ds_name) rval = ogr_ds.DeleteLayer(layer_name) else: ogr_ds = driver.CreateDataSource(ds_name) if ogr_ds is None: print "Create layer '%s' failed" % ds_name return (None, None) ogr_layer = ogr_ds.CreateLayer(layer_name, sref, ogr.wkbPoint) fieldDefn = ogr.FieldDefn(ID_FIELDNAME, ogr.OFTInteger) ogr_layer.CreateField(fieldDefn) return (ogr_ds, ogr_layer) def saveIntersections(ogr_layer, intersectionList): global fename1_fieldname, fename2_fieldname, modifier_fieldname featureDefn = ogr_layer.GetLayerDefn() not_a_point = 0 fid = 0 for (p, keytuple, fename1, fename2, modifier, rating) in intersectionList: if p.type == "Point": wkt = shapely.wkt.dumps(p) feature = ogr.Feature(featureDefn) feature.SetGeometry(ogr.CreateGeometryFromWkt(wkt)) fid += 1 feature.SetField("id", fid); feature.SetField(fename1_fieldname, fename1) feature.SetField(fename2_fieldname, fename2) feature.SetField(rating_fieldname, rating) feature.SetField(modifier_fieldname, modifier) ogr_layer.CreateFeature(feature) # Now create a second feature with the streetnames reversed. fid += 1 feature.SetField("id", fid); feature.SetField(fename1_fieldname, fename2) feature.SetField(fename2_fieldname, fename1) feature.SetField(modifier_fieldname, modifier) ogr_layer.CreateFeature(feature) feature.Destroy() else: not_a_point += 1 return fid