def time_difference(self):
pygeos.difference(self.left, self.right)
def time_difference_prec2(self):
pygeos.difference(self.left, self.right, grid_size=2)
bnd = bnd_df.geometry.values.data[0]
sarp_bnd = bnd_df.loc[bnd_df.id == "se"].geometry.values.data[0]
bnd_geo = bnd_df.to_crs(GEO_CRS)
bnd_geo["bbox"] = pg.bounds(bnd_geo.geometry.values.data).round(2).tolist()
# used to render maps
with open(ui_dir / "region_bounds.json", "w") as out:
out.write(bnd_geo[["id", "bbox"]].to_json(orient="records"))
# create mask
world = pg.box(-180, -85, 180, 85)
bnd_mask = bnd_geo.copy()
bnd_mask["geometry"] = pg.normalize(
pg.difference(world, bnd_mask.geometry.values.data))
write_dataframe(bnd_mask, out_dir / "region_mask.gpkg")
### Extract HUC4 units that intersect boundaries
print("Extracting HUC2...")
# First determine the HUC2s that overlap the region
huc2_df = (read_dataframe(
wbd_gdb, layer="WBDHU2",
columns=["huc2"]).to_crs(CRS).rename(columns={"huc2": "HUC2"}))
tree = pg.STRtree(huc2_df.geometry.values.data)
# First extract SARP HUC2
sarp_ix = tree.query(sarp_bnd, predicate="intersects")
sarp_huc2_df = huc2_df.iloc[sarp_ix].reset_index(drop=True)
f"Cutting NHD waterbodies by {len(breaks):,} breaks at dams to prevent dissolving together"
)
# find all pairs of waterbody and breaks, aggregate
# breaks by waterbody, then calculate difference
tree = pg.STRtree(df.geometry.values.data)
left, right = tree.query_bulk(breaks, predicate="intersects")
pairs = pd.DataFrame(
{"break_geometry": breaks.take(left)}, index=df.index.take(right)
)
grouped = pairs.groupby(level=0).break_geometry.apply(
lambda g: pg.multipolygons(g.values.data)
)
df.loc[grouped.index, "geometry"] = pg.difference(
df.loc[grouped.index].geometry.values.data, grouped.values
)
df = explode(df).reset_index(drop=True)
# make sure all polygons are valid
ix = ~pg.is_valid(df.geometry.values.data)
if ix.sum():
print(f"Repairing {ix.sum()} invalid waterbodies")
df.loc[ix, "geometry"] = pg.make_valid(df.loc[ix].geometry.values.data)
df = explode(explode(df))
df = df.loc[pg.get_type_id(df.geometry.values.data) == 3].reset_index()
# assign a new unique wbID
df["wbID"] = df.index.values.astype("uint32") + 1 + int(huc2) * 1000000
df["km2"] = pg.area(df.geometry.values.data) / 1e6
range_df = read_dataframe("data/boundaries/src/species_ranges.shp")
# split hoary bat into Hawaiian vs mainland
laci = range_df.loc[range_df.SCI_NAME == "Lasiurus cinereus"]
Hawaii = pg.box(*HAWAII_BOUNDS)
haba = laci.copy()
# add new geometry for haba
haba.geometry = pg.intersection(laci.geometry.values.data, Hawaii)
haba.SCI_NAME = SPECIES["haba"]["SNAME"]
haba.COMMON_NAM = SPECIES["haba"]["CNAME"]
range_df = range_df.append(haba, ignore_index=True, sort=False)
# clip out Hawaii from laci
range_df.loc[range_df.SCI_NAME == "Lasiurus cinereus",
"geometry"] = pg.difference(laci.geometry.values.data, Hawaii)
# add in alias of Myotis melanorhinus to Myotis ciliolabrum
sci_name_lut["Myotis melanorhinus"] = "myci"
range_df["species"] = range_df.SCI_NAME.map(sci_name_lut)
# dissolve on species
range_df = range_df.dissolve(by="species").reset_index()
range_df.to_feather(boundaries_dir / "species_ranges.feather")
write_dataframe(range_df, boundaries_dir / "species_ranges.json")
# for verification
# write_dataframe(range_df, "/tmp/species_ranges.gpkg")
### Process grids
print("Processing GRTS grid...")
bnd_df = gp.GeoDataFrame(
geometry=[pg.union_all(pg.make_valid(bnd_df.geometry.values.data))],
index=[0],
crs=bnd_df.crs,
)
bnd_df.to_feather(out_dir / "se_boundary.feather")
write_dataframe(bnd_df, data_dir / "boundaries/se_boundary.fgb")
# create GeoJSON for tiling
bnd_geo = bnd_df.to_crs(GEO_CRS)
write_dataframe(bnd_geo, tile_dir / "se_boundary.geojson", driver="GeoJSONSeq")
### Create mask by cutting SA bounds out of world bounds
print("Creating mask...")
world = pg.box(-180, -85, 180, 85)
mask = pg.normalize(pg.difference(world, bnd_geo.geometry.values.data))
write_dataframe(
gp.GeoDataFrame({"geometry": mask}, index=[0], crs=GEO_CRS),
tile_dir / "se_mask.geojson",
driver="GeoJSONSeq",
)
### Extract counties within SA bounds
print("Extracting states and counties...")
states = (read_dataframe(
src_dir / "boundaries/tl_2019_us_state.shp",
read_geometry=False,
columns=["STATEFP", "NAME"],
).rename(columns={
"NAME": "state"
def cut_lines_by_waterbodies(flowlines, joins, waterbodies, wb_joins, out_dir):
"""
Cut lines by waterbodies.
1. Intersects all previously intersected flowlines with waterbodies.
2. For those that cross but are not completely contained by waterbodies, cut them.
3. Evaluate the cuts, only those that have substantive cuts inside and outside are retained as cuts.
4. Any flowlines that are not contained or crossing waterbodies are dropped from joins
Parameters
----------
flowlines : GeoDataFrame
joins : DataFrame
flowline joins
waterbodies : GeoDataFrame
wb_joins : DataFrame
waterbody flowline joins
outdir : pathlib.Path
output directory for writing error files, if needed
Returns
-------
tuple of (GeoDataFrame, DataFrame, GeoDataFrame, DataFrame)
(flowlines, joins, waterbodies, waterbody joins)
"""
start = time()
fl_geom = flowlines.loc[flowlines.index.isin(wb_joins.lineID), ["geometry"]].copy()
# Many waterbodies have interior polygons (islands); these break the analysis below for cutting lines
# Extract a new polygon of just their outer boundary
wb_geom = waterbodies[["geometry"]].copy()
wb_geom["waterbody"] = pg.polygons(pg.get_exterior_ring(wb_geom.geometry))
print("Validating waterbodies...")
ix = ~pg.is_valid(wb_geom.waterbody)
invalid_count = ix.sum()
if invalid_count:
print("{:,} invalid waterbodies found, repairing...".format(invalid_count))
# Buffer by 0 to fix
# TODO: may need to do this by a small fraction and simplify instead
repair_start = time()
wb_geom.loc[ix, "waterbody"] = pg.buffer(wb_geom.loc[ix].waterbody, 0)
waterbodies.loc[ix, "geometry"] = wb_geom.loc[ix].waterbody
print("Repaired geometry in {:.2f}s".format(time() - repair_start))
# Set indices and create combined geometry object for analysis
wb_joins = wb_joins.set_index(["lineID", "wbID"])
geoms = wb_joins.join(fl_geom, how="inner").join(wb_geom.waterbody)
### Find contained geometries
print(
"Identifying flowlines completely within waterbodies out of {:,} flowline / waterbody combinations...".format(
len(geoms)
)
)
contained_start = time()
geoms["inside"] = pg.contains(geoms.waterbody.values, geoms.geometry.values)
print(
"Identified {:,} flowlines completely contained by waterbodies in {:.2f}s".format(
geoms.inside.sum(), time() - contained_start
)
)
# Check for logic errors - no flowline should be completely contained by more than 1 waterbody
errors = geoms.groupby(level=[0]).inside.sum().astype("uint8") > 1
if errors.max():
# this most likely indicates duplicate waterbodies, which should have been resolved before this
print(
"ERROR: major logic error - some flowlines claim to be completely contained by multiple waterbodies"
)
print(
"===> error flowlines written to {}/contained_errors.feather".format(
out_dir
)
)
to_geofeather(
flowlines.loc[flowlines.index.isin(errors)],
out_dir / "contained_errors.feather",
crs=CRS,
)
### Check those that aren't contained to see if they cross
print("Determining which flowlines actually cross into waterbodies...")
cross_start = time()
geoms = geoms.loc[~geoms.inside].copy()
geoms["crosses"] = pg.crosses(geoms.geometry, geoms.waterbody)
outside = geoms.loc[~(geoms["crosses"] | geoms.inside)].index
# keep the ones that cross for further processing
geoms = geoms.loc[geoms.crosses].copy()
print(
"Identified {:,} flowlines completely outside waterbodies and {:,} flowlines that cross waterbody boundaries in {:.2f}s".format(
len(outside), len(geoms), time() - cross_start
)
)
# Any that do not cross and are not completely within waterbodies should be dropped now
# Can only drop joins by BOTH lineID and wbID (the index here)
# Also drop associated waterbodies that no longer have joins
wb_joins = wb_joins.loc[~wb_joins.index.isin(outside)].copy()
# FIXME: for closely adjacent waterbodies, these are important to keep
# Need to cut them by their multiple polys, update their joins, and feed back into following analysis
# pg.intersection_all might work here
# check for multiple crossings - these are errors from NHD that we can drop from here
errors = geoms.groupby(level=0).size() > 1
if errors.max():
print(
"Found {:,} flowlines that cross multiple waterbodies. These are bad data and will be dropped from waterbody intersection.".format(
errors.sum()
)
)
to_geofeather(
flowlines.loc[errors.index].reset_index(),
out_dir / "error_crosses_multiple.feather",
crs=CRS,
)
# completely remove the flowlines from intersections and drop the waterbodies
wb_joins = wb_joins.loc[
~wb_joins.index.get_level_values(0).isin(errors.loc[errors].index)
].copy()
waterbodies = waterbodies.loc[
waterbodies.index.isin(wb_joins.index.get_level_values(1))
].copy()
geoms = geoms.loc[geoms.index.isin(wb_joins.index)].copy()
print("Calculating geometric intersection of flowlines and waterbodies...")
int_start = time()
geoms = geoms[["geometry", "waterbody"]].join(flowlines.length.rename("origLength"))
# First, calculate the geometric intersection between the lines and waterbodies
# WARNING: this intersection may return LineString, MultiLineString, Point, GeometryCollection
geoms["intersection"] = pg.intersection(geoms.geometry, geoms.waterbody)
types = pg.get_type_id(geoms.intersection)
# NOTE: all the points should be captured by the above logic for crosses
is_point = types.isin([0, 4])
is_line = types.isin([1, 5])
others = types[~(is_point | is_line)].unique()
# GeometryCollection indicates a mess, skip those
if len(others):
print(
"WARNING: Found other types of geometric intersection: {} (n={:,}), these will be dropped".format(
others, len(types[~(is_point | is_line)])
)
)
# Any that intersect only at a point are OUTSIDE
outside = geoms.loc[is_point].index # TODO: confirm this works
wb_joins = wb_joins.loc[~wb_joins.index.isin(outside)].copy()
print("Identified {:,} more flowlines outside waterbodies".format(len(outside)))
# Drop those that are not lines from further analysis
geoms = geoms.loc[is_line].copy()
# Inspect amount of overlay - if the intersected length is within 1m of final length, it is completely within
# if it is near 0, it is completely outside
geoms["length"] = pg.length(geoms.intersection)
outside = geoms.length < 1
inside = (geoms.origLength - geoms.length).abs() < 1
print(
"Found {:,} more completely outside, {:,} completely inside".format(
outside.sum(), inside.sum()
)
)
# drop the ones that are outside
wb_joins = wb_joins.loc[~wb_joins.index.isin(outside[outside].index)].copy()
# cut the ones that aren't completely inside or outside
geoms = geoms.loc[~(inside | outside)].copy()
print("Done evaluating intersection in {:.2f}s".format(time() - int_start))
if len(geoms):
print("Cutting {:,} flowlines ...".format(len(geoms)))
cut_start = time()
geoms = geoms[["geometry", "waterbody", "origLength"]]
# WARNING: difference is not precise, the point of split is not exactly at the intersection between lines
# but within some tolerance. This will cause them to fail the contains() test below.
boundary = pg.boundary(geoms.waterbody)
geoms["geometry"] = pg.difference(geoms.geometry, boundary)
errors = ~pg.is_valid(geoms.geometry)
if errors.max():
print("WARNING: geometry errors for {:,} cut lines".format(errors.sum()))
length = pg.length(geoms.geometry)
errors = (length - geoms.origLength).abs() > 1
if errors.max():
print(
"WARNING: {:,} lines were not completely cut by waterbodies (maybe shared edge?).\nThese will not be cut".format(
errors.sum()
)
)
to_geofeather(
flowlines.loc[
errors.loc[errors].index.get_level_values(0).unique()
].reset_index(),
out_dir / "error_incomplete_cut.feather",
crs=CRS,
)
# remove these from the cut geoms and retain their originals
geoms = geoms.loc[~errors].copy()
# Explode the multilines into single line segments
geoms["geometry"] = explode(geoms.geometry)
geoms = geoms.explode("geometry")
# mark those parts of the cut lines that are within waterbodies
# WARNING: this is not capturing all that should be inside after cutting!
geoms["iswithin"] = pg.contains(geoms.waterbody, geoms.geometry)
errors = geoms.groupby(level=0).iswithin.max() == False
if errors.max():
print(
"WARNING: {:,} flowlines that cross waterbodies had no parts contained within those waterbodies".format(
errors.sum()
)
)
to_geofeather(
flowlines.loc[errors.index].reset_index(),
out_dir / "error_crosses_but_not_contained.feather",
crs=CRS,
)
# If they cross, assume they are within
print("Attempting to correct these based on which ones cross")
ix = geoms.loc[
geoms.index.get_level_values(0).isin(errors.loc[errors].index)
].index
geoms.loc[ix, "iswithin"] = pg.crosses(
geoms.loc[ix].geometry, geoms.loc[ix].waterbody
)
errors = geoms.groupby(level=0).iswithin.max() == False
print("{:,} still have no part in a waterbody".format(errors.sum()))
# calculate total length of within and outside parts
geoms["length"] = pg.length(geoms.geometry)
# drop any new segments that are < 1m, these are noise
print("Dropping {:,} new segments < 1m".format((geoms.length < 1).sum()))
geoms = geoms.loc[geoms.length >= 1].copy()
if len(geoms) > 1:
length = geoms.groupby(["lineID", "wbID", "iswithin"]).agg(
{"length": "sum", "origLength": "first"}
)
# Anything within 1 meter of original length is considered unchanged
# This is so that we ignore slivers
length["unchanged"] = (length.origLength - length["length"]).abs() < 1
unchanged = (
length[["unchanged"]]
.reset_index()
.groupby(["lineID", "wbID"])
.unchanged.max()
.rename("max_unchanged")
)
unchanged = (
length.reset_index().set_index(["lineID", "wbID"]).join(unchanged)
)
is_within = (
unchanged.loc[unchanged.max_unchanged]
.reset_index()
.set_index(["lineID", "wbID"])
.iswithin
)
# For any that are unchanged and NOT within waterbodies,
# remove them from wb_joins
ix = is_within.loc[~is_within].index
wb_joins = wb_joins.loc[~wb_joins.index.isin(ix)].copy()
# Remove any that are unchanged from intersection analysis
geoms = geoms.loc[~geoms.index.isin(is_within.index)].copy()
print(
"Created {:,} new flowlines by splitting {:,} flowlines at waterbody edges in {:.2f}".format(
len(geoms),
len(geoms.index.get_level_values(0).unique()),
time() - cut_start,
)
)
if len(geoms) > 1:
### These are our final new lines to add
# remove their lineIDs from flowlines and append
# replace their outer joins to these ones and add intermediates
# Join in previous line information from flowlines
new_lines = (
geoms[["geometry", "length", "iswithin"]]
.reset_index()
.set_index("lineID")
.join(flowlines.drop(columns=["geometry", "length", "sinuosity"]))
.reset_index()
.rename(columns={"lineID": "origLineID", "iswithin": "waterbody"})
)
error = (
new_lines.groupby("origLineID").wbID.unique().apply(len).max() > 1
)
if error:
# Watch for errors - if a flowline is cut by multiple waterbodies
# there will be problems with our logic for splicing in new lines
# also - our intersection logic above is wrong
print(
"""\n========\n
MAJOR LOGIC ERROR: multiple waterbodies associated with a single flowline that as been cut.
\n========\n
"""
)
# recalculate length and sinuosity
new_lines["length"] = pg.length(new_lines.geometry).astype("float32")
new_lines["sinuosity"] = calculate_sinuosity(new_lines.geometry).astype(
"float32"
)
# calculate new IDS
next_segment_id = int(flowlines.index.max() + 1)
new_lines["lineID"] = next_segment_id + new_lines.index
new_lines.lineID = new_lines.lineID.astype("uint32")
### Update waterbody joins
# remove joins replaced by above
ix = new_lines.set_index(["origLineID", "wbID"]).index
wb_joins = wb_joins.loc[~wb_joins.index.isin(ix)].copy()
# add new joins
wb_joins = (
wb_joins.reset_index()
.append(
new_lines.loc[new_lines.waterbody, ["lineID", "wbID"]],
ignore_index=True,
sort=False,
)
.set_index(["lineID", "wbID"])
)
### Update flowline joins
# transform new lines to create new joins
l = new_lines.groupby("origLineID").lineID
# the first new line per original line is the furthest upstream, so use its
# ID as the new downstream ID for anything that had this origLineID as its downstream
first = l.first().rename("new_downstream_id")
# the last new line per original line is the furthest downstream...
last = l.last().rename("new_upstream_id")
# Update existing joins with the new lineIDs we created at the upstream or downstream
# ends of segments we just created
joins = update_joins(
joins,
first,
last,
downstream_col="downstream_id",
upstream_col="upstream_id",
)
### Create new line joins for any that weren't inserted above
# Transform all groups of new line IDs per original lineID, wbID
# into joins structure
pairs = lambda a: pd.Series(zip(a[:-1], a[1:]))
new_joins = (
new_lines.groupby(["origLineID", "wbID"])
.lineID.apply(pairs)
.apply(pd.Series)
.reset_index()
.rename(columns={0: "upstream_id", 1: "downstream_id"})
.join(
flowlines[["NHDPlusID", "loop"]].rename(
columns={"NHDPlusID": "upstream"}
),
on="origLineID",
)
)
# NHDPlusID is same for both sides
new_joins["downstream"] = new_joins.upstream
new_joins["type"] = "internal"
new_joins = new_joins[
[
"upstream",
"downstream",
"upstream_id",
"downstream_id",
"type",
"loop",
]
]
joins = joins.append(
new_joins, ignore_index=True, sort=False
).sort_values(["downstream_id", "upstream_id"])
### Update flowlines
# remove originals now replaced by cut versions here
flowlines = (
flowlines.loc[~flowlines.index.isin(new_lines.origLineID)]
.reset_index()
.append(
new_lines[["lineID"] + list(flowlines.columns) + ["waterbody"]],
ignore_index=True,
sort=False,
)
.sort_values("lineID")
.set_index("lineID")
)
# End cut geometries
# Update waterbody bool for other flowlines based on those that completely intersected
# above
flowlines.loc[
flowlines.index.isin(wb_joins.index.get_level_values(0).unique()), "waterbody"
] = True
flowlines.waterbody = flowlines.waterbody.fillna(False)
### Update waterbodies and calculate flowline stats
wb_joins = wb_joins.reset_index()
stats = (
wb_joins.join(flowlines.length.rename("flowlineLength"), on="lineID")
.groupby("wbID")
.flowlineLength.sum()
.astype("float32")
)
waterbodies = waterbodies.loc[waterbodies.index.isin(wb_joins.wbID)].join(stats)
print("Done cutting flowlines by waterbodies in {:.2f}s".format(time() - start))
return flowlines, joins, waterbodies, wb_joins
data_dir = Path("data")
out_dir = data_dir / "inputs/boundaries" # used as inputs for other steps
tile_dir = data_dir / "for_tiles"
sa_df = read_dataframe(src_dir / "boundaries/SABlueprint2020_Extent.shp")
### Create mask by cutting SA bounds out of world bounds
print("Creating mask...")
world = pg.box(-180, -85, 180, 85)
# boundary has self-intersections and 4 geometries, need to clean up
bnd = pg.union_all(pg.make_valid(sa_df.geometry.values.data))
bnd_geo = pg.union_all(
pg.make_valid(sa_df.to_crs(GEO_CRS).geometry.values.data))
mask = pg.normalize(pg.difference(world, bnd_geo))
gp.GeoDataFrame(geometry=[bnd],
crs=DATA_CRS).to_feather(out_dir / "sa_boundary.feather")
write_dataframe(
gp.GeoDataFrame({"geometry": bnd_geo}, index=[0], crs=GEO_CRS),
tile_dir / "sa_boundary.geojson",
driver="GeoJSONSeq",
)
write_dataframe(
gp.GeoDataFrame({"geometry": mask}, index=[0], crs=GEO_CRS),
tile_dir / "sa_mask.geojson",
driver="GeoJSONSeq",
)
sarp_states = sarp_state_df.STATEFIPS.unique()
# Clip HUC4 areas outside state boundaries; these are remainder
state_merged = pg.coverage_union_all(state_df.geometry.values.data)
# find all that intersect but are not contained
tree = pg.STRtree(huc4_df.geometry.values.data)
intersects_ix = tree.query(state_merged, predicate="intersects")
contains_ix = tree.query(state_merged, predicate="contains")
ix = np.setdiff1d(intersects_ix, contains_ix)
outer_huc4 = huc4_df.iloc[ix].copy()
outer_huc4["km2"] = pg.area(outer_huc4.geometry.values.data) / 1e6
# calculate geometric difference, explode, and keep non-slivers
outer_huc4["geometry"] = pg.difference(outer_huc4.geometry.values.data,
state_merged)
outer_huc4 = explode(outer_huc4)
outer_huc4["clip_km2"] = pg.area(outer_huc4.geometry.values.data) / 1e6
outer_huc4["percent"] = 100 * outer_huc4.clip_km2 / outer_huc4.km2
keep_huc4 = outer_huc4.loc[outer_huc4.clip_km2 >= 100].HUC4.unique()
outer_huc4 = outer_huc4.loc[outer_huc4.HUC4.isin(keep_huc4)
& (outer_huc4.clip_km2 >= 2.5)].copy()
outer_huc4 = dissolve(outer_huc4, by="HUC4", agg={
"HUC2": "first"
}).reset_index(drop=True)
outer_huc4.to_feather(out_dir / "outer_huc4.feather")
write_dataframe(outer_huc4, out_dir / "outer_huc4.gpkg")
### Counties - within HUC4 bounds
print("Processing counties")
fips = sorted(state_df.STATEFIPS.unique())
