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2 changed files with 540 additions and 323 deletions

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@ -14,3 +14,37 @@ which will individually be transformed into rectangles which are also plotted.
On Debian systems you need the following packages: On Debian systems you need the following packages:
apt-get install python python-pil python-scipy python-tk python-matplotlib python-numpy apt-get install python python-pil python-scipy python-tk python-matplotlib python-numpy
how to setup postgresql+postgis locally without root
----------------------------------------------------
/usr/lib/postgresql/14/bin/initdb -D /tmp/postgres
/usr/lib/postgresql/14/bin/postgres --port=5433 --unix_socket_directories=/tmp/postgres -D /tmp/postgres &
/usr/lib/postgresql/14/bin/createdb --port=5433 --host=/tmp/postgres gis
/usr/lib/postgresql/14/bin/psql --port=5433 --host=/tmp/postgres gis -c 'CREATE EXTENSION postgis;' -c 'CREATE EXTENSION hstore;'
osm2pgsql --port=5433 --host=/tmp/postgres -d gis --create --slim -G --hstore --tag-transform-script /tmp/openstreetmap-carto/openstreetmap-carto.lua -S /tmp/openstreetmap-carto/openstreetmap-carto.style ~/Downloads/map.xml
/usr/lib/postgresql/14/bin/psql --port=5433 --host=/tmp/postgres gis -f /tmp/openstreetmap-carto/indexes.sql
openstreetmap-carto:
scripts/get-external-data.py --port=5433 --host=/tmp/postgres
diff --git a/project.mml b/project.mml
index 7fb3d47..d8014f8 100644
--- a/project.mml
+++ b/project.mml
@@ -27,6 +27,8 @@ _parts:
osm2pgsql: &osm2pgsql
type: "postgis"
dbname: "gis"
+ port: "5433"
+ host: "/tmp/postgres"
key_field: ""
geometry_field: "way"
extent: "-20037508,-20037508,20037508,20037508"
# the database connection settings are part of the style xml!
carto project.mml > mapnik.xml
nik4 --url https://www.openstreetmap.org/\#map\=12/49.7731/9.6726 /tmp/openstreetmap-carto/mapnik.xml screenshot.svg

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@ -1,6 +1,6 @@
#!/usr/bin/env python #!/usr/bin/env python3
# #
# Copyright (C) 2014 Johannes Schauer <j.schauer@email.de> # Copyright (C) 2014 - 2021 Johannes Schauer Marin Rodrigues <josch@mister-muffin.de>
# #
# This program is free software: you can redistribute it and/or modify # This program is free software: you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by # it under the terms of the GNU General Public License as published by
@ -15,28 +15,52 @@
# You should have received a copy of the GNU General Public License # You should have received a copy of the GNU General Public License
# along with this program. If not, see <http://www.gnu.org/licenses/>. # along with this program. If not, see <http://www.gnu.org/licenses/>.
import os
import math import math
from math import sqrt from math import sqrt
import numpy as np import numpy
import matplotlib.pyplot as plt
from scipy import interpolate from scipy import interpolate
from itertools import tee, izip from itertools import tee
from matplotlib.patches import Polygon from PIL import Image, ImageDraw
from matplotlib.collections import PatchCollection import urllib.request
import matplotlib import matplotlib.path
from PIL import Image import matplotlib.transforms
import xml.etree.ElementTree as ET
import mapnik
import cairo
def y2lat(a): TILESIZE = 256
return 180.0/math.pi*(2.0*math.atan(math.exp(a*math.pi/180.0))-math.pi/2.0) EARTHRADIUS = 6378137
def haversine(lon1, lat1, lon2, lat2):
lon1 = math.radians(lon1)
lat1 = math.radians(lat1)
lon2 = math.radians(lon2)
lat2 = math.radians(lat2)
dlon = lon2 - lon1
dlat = lat2 - lat1
a = (
math.sin(dlat / 2) ** 2
+ math.cos(lat1) * math.cos(lat2) * math.sin(dlon / 2) ** 2
)
return EARTHRADIUS * 2 * math.asin(math.sqrt(a))
def lat2y(lat, zoom):
return math.log(math.tan(math.pi / 4 + math.radians(lat) / 2)) * EARTHRADIUS
def lon2x(lon, zoom):
return math.radians(lon) * EARTHRADIUS
def lat2y(a):
return 180.0/math.pi*math.log(math.tan(math.pi/4.0+a*(math.pi/180.0)/2.0))
def pairwise(iterable): def pairwise(iterable):
"s -> (s0,s1), (s1,s2), (s2,s3), ..." "s -> (s0,s1), (s1,s2), (s2,s3), ..."
a, b = tee(iterable, 2) a, b = tee(iterable, 2)
next(b, None) next(b, None)
return izip(a, b) return zip(a, b)
def triplewise(iterable): def triplewise(iterable):
"s -> (s0,s1,s2), (s1,s2,s3), (s2,s3,s4), ..." "s -> (s0,s1,s2), (s1,s2,s3), (s2,s3,s4), ..."
@ -44,105 +68,131 @@ def triplewise(iterable):
next(b, None) next(b, None)
next(c, None) next(c, None)
next(c, None) next(c, None)
return izip(a,b,c) return zip(a, b, c)
# using barycentric coordinates
def ptInTriangle(p, p0, p1, p2):
A = 0.5 * (-p1[1] * p2[0] + p0[1] * (-p1[0] + p2[0]) + p0[0] * (p1[1] - p2[1]) + p1[0] * p2[1]);
sign = -1 if A < 0 else 1;
s = (p0[1] * p2[0] - p0[0] * p2[1] + (p2[1] - p0[1]) * p[0] + (p0[0] - p2[0]) * p[1]) * sign;
t = (p0[0] * p1[1] - p0[1] * p1[0] + (p0[1] - p1[1]) * p[0] + (p1[0] - p0[0]) * p[1]) * sign;
return s >= 0 and t >= 0 and (s + t) <= 2 * A * sign;
def getxing(p0, p1, p2, p3): def intersects(p0, p1, p2, p3):
ux = p1[0]-p0[0] s10_x = p1[0] - p0[0]
uy = p1[1]-p0[1] s10_y = p1[1] - p0[1]
vx = p2[0]-p3[0] s32_x = p3[0] - p2[0]
vy = p2[1]-p3[1] s32_y = p3[1] - p2[1]
# get multiplicity of u at which u meets v
a = vy*ux-vx*uy
if a == 0:
# lines are parallel and never meet
return None
s = (vy*(p3[0]-p0[0])+vx*(p0[1]-p3[1]))/a
if 0.0 < s < 1.0:
return (p0[0]+s*ux, p0[1]+s*uy)
else:
return None
# the line p0-p1 is the upper normal to the path denom = s10_x * s32_y - s32_x * s10_y
# the line p2-p3 is the lower normal to the path
#
# | | |
# p0--------|--------p1
# | | |
# | | |
# p3--------|--------p2
# | | |
def ptInQuadrilateral(p, p0, p1, p2, p3):
# it might be that the two normals cross at some point
# in that case the two triangles are created differently
cross = getxing(p0, p1, p2, p3)
if cross:
return ptInTriangle(p, p0, cross, p3) or ptInTriangle(p, p2, cross, p1)
else:
return ptInTriangle(p, p0, p1, p2) or ptInTriangle(p, p2, p3, p0)
def get_st(Ax,Ay,Bx,By,Cx,Cy,Dx,Dy,Xx,Xy): if denom == 0:
d = Bx-Ax-Cx+Dx return False # collinear
e = By-Ay-Cy+Dy
l = Dx-Ax denom_is_positive = denom > 0
g = Dy-Ay
h = Cx-Dx s02_x = p0[0] - p2[0]
m = Cy-Dy s02_y = p0[1] - p2[1]
i = Xx-Dx
j = Xy-Dy s_numer = s10_x * s02_y - s10_y * s02_x
n = g*h-m*l
# calculation for s if (s_numer < 0) == denom_is_positive:
a1 = m*d-h*e return False # no collision
b1 = n-j*d+i*e
c1 = l*j-g*i t_numer = s32_x * s02_y - s32_y * s02_x
# calculation for t
a2 = g*d-l*e if (t_numer < 0) == denom_is_positive:
b2 = n+j*d-i*e return False # no collision
c2 = h*j-m*i
s = [] if (s_numer > denom) == denom_is_positive or (t_numer > denom) == denom_is_positive:
if a1 == 0: return False # no collision
s.append(-c1/b1)
else: return True
r1 = b1*b1-4*a1*c1
if r1 >= 0:
r11 = (-b1+sqrt(r1))/(2*a1) def main():
if -0.0000000001 <= r11 <= 1.0000000001: import sys
s.append(r11)
r12 = (-b1-sqrt(r1))/(2*a1) if len(sys.argv) != 4:
if -0.0000000001 <= r12 <= 1.0000000001: print("usage: %s data.gpx mapwidth paperwidth" % sys.argv[0])
s.append(r12) exit(1)
t = []
if a2 == 0: zoom = 10
t.append(-c2/b2) latmin = math.inf
else: latmax = -1
r2 = b2*b2-4*a2*c2
if r2 >= 0: path = []
r21 = (-b2+sqrt(r2))/(2*a2) with open(sys.argv[1]) as f:
if -0.0000000001 <= r21 <= 1.0000000001: root = ET.parse(f)
t.append(r21) for trkpt in root.findall(
r22 = (-b2-sqrt(r2))/(2*a2) "./gpx:trk/gpx:trkseg/gpx:trkpt",
if -0.0000000001 <= r22 <= 1.0000000001: {"gpx": "http://www.topografix.com/GPX/1/1"},
t.append(r22) ):
if not s or not t: lat = float(trkpt.attrib["lat"])
return [],[] lon = float(trkpt.attrib["lon"])
if len(s) == 1 and len(t) == 2: if lat < latmin:
s = [s[0],s[0]] latmin = lat
if len(s) == 2 and len(t) == 1: if lat > latmax:
t = [t[0],t[0]] latmax = lat
return s, t # apply mercator projection
path.append((lon, lat))
merc = mapnik.Projection('+proj=merc +a=6378137 +b=6378137 +lat_ts=0.0 +lon_0=0.0 +x_0=0.0 +y_0=0 +k=1.0 +units=m +nadgrids=@null +no_defs +over')
longlat = mapnik.Projection('+proj=longlat +ellps=WGS84 +datum=WGS84 +no_defs')
#m = mapnik.Map(800, 600)
#mapnik.load_map_from_string(m, open("/tmp/openstreetmap-carto/mapnik.xml").read(), False, "/tmp/openstreetmap-carto/")
#gpxstyle = mapnik.Style()
#gpxrule = mapnik.Rule()
#gpxsym = mapnik.LineSymbolizer()
#gpxsym.stroke = mapnik.Color('red')
#gpxsym.stroke_width = 5
#gpxsym.stroke_opacity = 0.5
#gpxrule.symbols.append(gpxsym)
#gpxstyle.rules.append(gpxrule)
#m.append_style('GPXStyle', gpxstyle)
#gpxlayer = mapnik.Layer('GPXLayer')
##gpxlayer.srs =
#gpxlayer.datasource = mapnik.Ogr(file = sys.argv[1], layer = 'tracks')
#gpxlayer.styles.append('GPXStyle')
#m.layers.append(gpxlayer)
#m.aspect_fix_mode = mapnik.aspect_fix_mode.GROW_BBOX
#m.srs = merc.params()
#m.zoom_to_box(mapnik.ProjTransform(longlat, merc).forward(gpxlayer.envelope()))
#mapnik.render_to_file(m, "out.png", "png", 1.0)
length = 0
for (lon1, lat1), (lon2, lat2) in pairwise(path):
length += haversine(lon1, lat1, lon2, lat2)
dpi = 96 # because we use bitmap tiles instead of vectors
mapwidthm = float(sys.argv[2]) # map width in m
paperwidthm = float(sys.argv[3]) # paper width in m
earth = 6378137 # earth equator radius in m
width = dpi / 0.0254 * paperwidthm # width in px
zoom = math.ceil(
math.log2(
2
* math.pi
* earth
* math.cos(math.radians((latmax + latmin) / 2))
* width
/ (mapwidthm * TILESIZE)
)
)
subdiv = math.ceil(4*length/mapwidthm)
subdiv = 40
width = 15000
print("zoom:", zoom)
print("length:", length)
print("subdiv:", subdiv)
path = [(lon2x(lon, zoom), lat2y(lat, zoom)) for lon, lat in path]
def main(x,y,width,smoothing,subdiv):
halfwidth = width / 2.0 halfwidth = width / 2.0
tck,u = interpolate.splprep([x,y],s=smoothing) found_smoothing = False
unew = np.linspace(0,1.0,subdiv+1) #for smoothing in [2 ** i for i in range(30)]:
for smoothing in [2 ** 35]:
tck, u = interpolate.splprep(list(zip(*path)), s=smoothing)
unew = numpy.linspace(0, 1.0, subdiv + 1)
out = interpolate.splev(unew, tck) out = interpolate.splev(unew, tck)
# prepend and append a segment
out = (
[2 * out[0][0] - out[0][1]] + list(out[0]) + [2 * out[0][-1] - out[0][-2]],
[2 * out[1][0] - out[1][1]] + list(out[1]) + [2 * out[1][-1] - out[1][-2]],
)
heights = [] heights = []
offs = [] offs = []
height = 0.0 height = 0.0
@ -201,165 +251,298 @@ def main(x,y,width,smoothing,subdiv):
qx.append(out[0][-1] + dx / dl) qx.append(out[0][-1] + dx / dl)
qy.append(out[1][-1] + dy / dl) qy.append(out[1][-1] + dy / dl)
quads = [] quads = []
patches = [] for (p2x, p2y, p1x, p1y), (p3x, p3y, p0x, p0y) in pairwise(zip(px, py, qx, qy)):
for (p3x,p3y,p2x,p2y),(p0x,p0y,p1x,p1y) in pairwise(zip(px,py,qx,qy)):
quads.append(((p0x, p0y), (p1x, p1y), (p2x, p2y), (p3x, p3y))) quads.append(((p0x, p0y), (p1x, p1y), (p2x, p2y), (p3x, p3y)))
polygon = Polygon(((p0x,p0y),(p1x,p1y),(p2x,p2y),(p3x,p3y)), True) # check for convex quads (sides intersect)
patches.append(polygon) have_convex = False
containingquad = [] for (p0, p1, p2, p3) in quads:
for pt in zip(x,y): if intersects(p0, p3, p1, p2):
# for each point, find the quadrilateral that contains it have_convex = True
found = []
for i,(p0,p1,p2,p3) in enumerate(quads):
if ptInQuadrilateral(pt,p0,p1,p2,p3):
found.append(i)
if found:
if len(found) > 1:
print "point found in two quads"
return None
containingquad.append(found[0])
else:
containingquad.append(None)
# check if the only points for which no quad could be found are in the
# beginning or in the end
# find the first missing ones:
for i,q in enumerate(containingquad):
if q != None:
break break
# find the last missing ones if have_convex:
for j,q in izip(xrange(len(containingquad)-1, -1, -1), reversed(containingquad)): print("have convex")
if q != None:
break
# remove the first and last missing ones
if i != 0 or j != len(containingquad)-1:
containingquad = containingquad[i:j+1]
x = x[i:j+1]
y = y[i:j+1]
# check if there are any remaining missing ones:
if None in containingquad:
print "cannot find quad for point"
return None
for off,h in zip(offs,heights):
targetquad = ((0,off+h),(width,off+h),(width,off),(0,off))
patches.append(Polygon(targetquad,True))
tx = []
ty = []
assert len(containingquad) == len(x) == len(y)
assert len(out[0]) == len(out[1]) == len(px) == len(py) == len(qx) == len(qy) == len(quads)+1 == len(heights)+1 == len(offs)+1
for (rx,ry),i in zip(zip(x,y),containingquad):
if i == None:
continue continue
(ax,ay),(bx,by),(cx,cy),(dx,dy) = quads[i] ## check for quads that look too much like a triangle
s,t = get_st(ax,ay,bx,by,cx,cy,dx,dy,rx,ry) # have_triangle = False
# if more than one solution, take second # for ((p00, p01), (p10, p11), (p20, p21), (p30, p31)) in quads:
# TODO: investigate if this is always the right solution # len1 = sqrt((p10-p00)**2+(p11-p01)**2)
if len(s) != 1 or len(t) != 1: # len2 = sqrt((p30-p20)**2+(p31-p21)**2)
s = s[1] # if len1/len2 > 100:
t = t[1] # have_triangle = True
else: # break
s = s[0] # if len2/len1 < 1/100:
t = t[0] # have_triangle = True
u = s*width # break
v = offs[i]+t*heights[i] # if have_triangle:
tx.append(u) # continue
ty.append(v) # draw
#sx = [] polygon = []
#sy = [] for ((p00, p01), (p10, p11), (p20, p21), (p30, p31)) in quads:
#for ((x1,y1),(x2,y2)),((ax,ay),(bx,by),(cx,cy),(dx,dy)),off,h in zip(pairwise(zip(*out)),quads,offs,heights): polygon.append((p10, p11))
# s,t = get_st(ax,ay,bx,by,cx,cy,dx,dy,x1,y1) polygon.append((p00, p01))
# if len(s) != 1 or len(t) != 1: for ((p00, p01), (p10, p11), (p20, p21), (p30, p31)) in reversed(quads):
# return None polygon.append((p30, p31))
# u = s[0]*width polygon.append((p20, p21))
# v = off+t[0]*h polygon.append(polygon[0])
# sx.append(u)
# sy.append(v)
# s,t = get_st(ax,ay,bx,by,cx,cy,dx,dy,x2,y2)
# if len(s) != 1 or len(t) != 1:
# return None
# u = s[0]*width
# v = off+t[0]*h
# sx.append(u)
# sy.append(v)
# create map with
# python -c 'import logging; logging.basicConfig(level=logging.DEBUG); from landez import ImageExporter; ie = ImageExporter(tiles_url="http://{s}.tile.opencyclemap.org/cycle/{z}/{x}/{y}.png"); ie.export_image(bbox=(8.0419921875,51.25160146817652,10.074462890625,54.03681240523652), zoomlevel=14, imagepath="image.png")'
im = Image.open("map.png")
bbox = [8.0419921875,51.25160146817652,10.074462890625,54.03681240523652]
# apply mercator projection
bbox[1] = lat2y(bbox[1])
bbox[3] = lat2y(bbox[3])
iw,ih = im.size
data = []
for i,(off,h,(p0,p1,p2,p3)) in enumerate(zip(offs,heights,quads)):
# first, account for the offset of the input image
p0 = p0[0]-bbox[0],p0[1]-bbox[1]
p1 = p1[0]-bbox[0],p1[1]-bbox[1]
p2 = p2[0]-bbox[0],p2[1]-bbox[1]
p3 = p3[0]-bbox[0],p3[1]-bbox[1]
# PIL expects coordinates in counter clockwise order
p1,p3 = p3,p1
# x lon
# ----- = -----
# w bbox[2]-bbox[0]
# translate to pixel coordinates
p0 = (iw*p0[0])/(bbox[2]-bbox[0]),(ih*p0[1])/(bbox[3]-bbox[1])
p1 = (iw*p1[0])/(bbox[2]-bbox[0]),(ih*p1[1])/(bbox[3]-bbox[1])
p2 = (iw*p2[0])/(bbox[2]-bbox[0]),(ih*p2[1])/(bbox[3]-bbox[1])
p3 = (iw*p3[0])/(bbox[2]-bbox[0]),(ih*p3[1])/(bbox[3]-bbox[1])
# PIL starts coordinate system at the upper left corner, swap y coord
p0 = int(p0[0]),int(ih-p0[1])
p1 = int(p1[0]),int(ih-p1[1])
p2 = int(p2[0]),int(ih-p2[1])
p3 = int(p3[0]),int(ih-p3[1])
box=(0,int(ih*(height-off-h)/(bbox[3]-bbox[1])),
int(iw*width/(bbox[2]-bbox[0])),int(ih*(height-off)/(bbox[3]-bbox[1])))
quad=(p0[0],p0[1],p1[0],p1[1],p2[0],p2[1],p3[0],p3[1])
data.append((box,quad))
im_out = im.transform((int(iw*width/(bbox[2]-bbox[0])),int(ih*height/(bbox[3]-bbox[1]))),Image.MESH,data,Image.BICUBIC)
im_out.save("out.png")
#np.random.seed(seed=0)
#colors = 100*np.random.rand(len(patches)/2)+100*np.random.rand(len(patches)/2)
#p = PatchCollection(patches, cmap=matplotlib.cm.jet, alpha=0.4)
#p.set_array(np.array(colors))
#plt.figure()
#plt.axes().set_aspect('equal')
##plt.axhspan(0, height, xmin=0, xmax=width)
#fig, ax = plt.subplots()
##ax.add_collection(p)
#ax.set_aspect('equal')
#plt.axis((0,width,0,height))
#plt.imshow(np.asarray(im_out),extent=[0,width,0,height])
#plt.imshow(np.asarray(im),extent=[bbox[0],bbox[2],bbox[1],bbox[3]])
#plt.plot(x,y,out[0],out[1],px,py,qx,qy,tx,ty)
#plt.show()
return True
if __name__ == '__main__': # check if path is inside polygon
x = [] if matplotlib.path.Path(polygon).contains_path(
y = [] matplotlib.path.Path(path)
import sys ):
if len(sys.argv) != 5: found_smoothing = True
print "usage: %s data.csv width smoothing N"%sys.argv[0] break
print "" print("doesn't contain path")
print " data.csv whitespace delimited lon/lat pairs of points along the path" if not found_smoothing:
print " width width of the resulting map in degrees" print("cannot find smoothing")
print " smoothing curve smoothing from 0 (exact fit) to higher values (looser fit)"
print " N amount of quads to split the path into"
print ""
print " example usage:"
print " %s Weser-Radweg-Hauptroute.csv 0.286 6 20"%sys.argv[0]
exit(1) exit(1)
with open(sys.argv[1]) as f: assert (
for l in f: len(out[0])
a,b = l.split() == len(out[1])
# apply mercator projection == len(px)
b = lat2y(float(b)) == len(py)
x.append(float(a)) == len(qx)
y.append(b) == len(qy)
width = float(sys.argv[2]) == len(quads) + 1
smoothing = float(sys.argv[3]) == len(heights) + 1
N = int(sys.argv[4]) == len(offs) + 1
main(x,y,width,smoothing,N) )
#for smoothing in [1,2,4,8,12]:
# for subdiv in range(10,30): minx = math.inf
# if main(x,y,width,smoothing,subdiv): maxx = -1
# print width,smoothing,subdiv miny = math.inf
maxy = -1
for (xi, yi) in polygon:
if xi < minx:
minx = xi
if xi > maxx:
maxx = xi
if yi < miny:
miny = yi
if yi > maxy:
maxy = yi
print(minx, maxx, miny, maxy)
m = mapnik.Map(800, 600)
mapnik.load_map_from_string(m, open("/tmp/openstreetmap-carto/mapnik.xml").read(), False, "/tmp/openstreetmap-carto/")
gpxstyle = mapnik.Style()
gpxrule = mapnik.Rule()
gpxsym = mapnik.LineSymbolizer()
gpxsym.stroke = mapnik.Color('blue')
gpxsym.stroke_width = 5
gpxsym.stroke_opacity = 0.5
gpxrule.symbols.append(gpxsym)
gpxstyle.rules.append(gpxrule)
m.append_style('GPXStyle', gpxstyle)
gpxlayer = mapnik.Layer('GPXLayer')
#gpxlayer.srs =
gpxlayer.datasource = mapnik.Ogr(file = sys.argv[1], layer = 'tracks')
gpxlayer.styles.append('GPXStyle')
m.layers.append(gpxlayer)
m.aspect_fix_mode = mapnik.aspect_fix_mode.GROW_BBOX
m.zoom_to_box(mapnik.Box2d(mapnik.Coord(minx, miny), mapnik.Coord(maxx, maxy)))
m.srs = merc.params()
surface = cairo.SVGSurface("out.svg", 800, 600)
ctx = cairo.Context(surface)
mapnik.render(m, ctx)
for pos in zip(*out):
pos = m.view_transform().forward(mapnik.Coord(*pos))
ctx.line_to(pos.x, pos.y)
ctx.set_source_rgb(0,0,0)
ctx.stroke()
for i, (p0, p1, p2, p3) in enumerate(quads):
p0 = m.view_transform().forward(mapnik.Coord(*p0))
p1 = m.view_transform().forward(mapnik.Coord(*p1))
p2 = m.view_transform().forward(mapnik.Coord(*p2))
p3 = m.view_transform().forward(mapnik.Coord(*p3))
if i == 1:
ctx.arc(p0.x, p0.y, 10, 0, 2*math.pi)
ctx.set_source_rgb(1,0,0)
ctx.fill()
ctx.arc(p1.x, p1.y, 10, 0, 2*math.pi)
ctx.set_source_rgb(0,1,0)
ctx.fill()
ctx.arc(p2.x, p2.y, 10, 0, 2*math.pi)
ctx.set_source_rgb(0,0,1)
ctx.fill()
ctx.arc(p3.x, p3.y, 10, 0, 2*math.pi)
ctx.set_source_rgb(1,1,0)
ctx.fill()
ctx.move_to(p0.x, p0.y)
ctx.line_to(p1.x, p1.y)
ctx.line_to(p2.x, p2.y)
ctx.line_to(p3.x, p3.y)
ctx.close_path()
ctx.set_source_rgb(1,0,0)
ctx.stroke()
surface.finish()
vertices = []
triangles = []
for i, (off, h, (p0, p1, p2, p3)) in enumerate(zip(offs, heights, quads)):
v1 = (p0[0], p0[1], width, off+h) # top right
v2 = (p1[0], p1[1], width, off) # bottom right
v3 = (p2[0], p2[1], 0, off) # bottom left
v4 = (p3[0], p3[1], 0, off+h) # top left
vertices.extend([v3, v2, v1])
triangles.append((len(vertices)-3, len(vertices)-2, len(vertices)-1))
vertices.extend([v3, v1, v4])
triangles.append((len(vertices)-3, len(vertices)-2, len(vertices)-1))
with open("/tmp/tinshift.json", "w") as f:
print("""
{
"file_type": "triangulation_file",
"format_version": "1.0",
"transformed_components": [ "horizontal" ],
"fallback_strategy": "nearest",
"vertices_columns": [ "source_x", "source_y", "target_x", "target_y" ],
"triangles_columns": [ "idx_vertex1", "idx_vertex2", "idx_vertex3" ],
"vertices": [ %s ],
"triangles": [ %s ]
}
""" % (','.join(["[ %f, %f, %f, %f ]"%v for v in vertices]), ','.join(["[%d, %d, %d]"%t for t in triangles])), file=f)
tinshift = mapnik.Projection("+proj=pipeline +step +proj=webmerc +step +proj=tinshift +file=/tmp/tinshift.json")
m = mapnik.Map(1600, int(1600*height/width))
mapnik.load_map_from_string(m, open("/tmp/openstreetmap-carto/mapnik.xml").read(), False, "/tmp/openstreetmap-carto/")
gpxstyle = mapnik.Style()
gpxrule = mapnik.Rule()
gpxsym = mapnik.LineSymbolizer()
gpxsym.stroke = mapnik.Color('blue')
gpxsym.stroke_width = 5
gpxsym.stroke_opacity = 0.5
gpxrule.symbols.append(gpxsym)
gpxstyle.rules.append(gpxrule)
m.append_style('GPXStyle', gpxstyle)
gpxlayer = mapnik.Layer('GPXLayer')
gpxlayer.datasource = mapnik.Ogr(file = sys.argv[1], layer = 'tracks')
gpxlayer.styles.append('GPXStyle')
m.layers.append(gpxlayer)
m.aspect_fix_mode = mapnik.aspect_fix_mode.GROW_BBOX
m.zoom_to_box(mapnik.Box2d(mapnik.Coord(0, 0), mapnik.Coord(width, height)))
m.srs = tinshift.params()
surface = cairo.PDFSurface("out.pdf", 1600, int(1600*height/width))
mapnik.render(m, surface)
surface.finish()
#minx = math.inf
#maxx = -1
#miny = math.inf
#maxy = -1
#for (xi, yi) in polygon:
# if xi < minx:
# minx = xi
# if xi > maxx:
# maxx = xi
# if yi < miny:
# miny = yi
# if yi > maxy:
# maxy = yi
#im1 = Image.new("RGB", (int(maxx - minx), int(maxy - miny)))
#im2 = Image.new("RGB", (int(maxx - minx), int(maxy - miny)))
#opener = urllib.request.build_opener()
#opener.addheaders = [("User-agent", "mapbender")]
#urllib.request.install_opener(opener)
#todl = []
#for i in range(int(minx / TILESIZE) - 1, int(maxx / TILESIZE) + 2):
# for j in range(int(miny / TILESIZE) - 1, int(maxy / TILESIZE) + 2):
# os.makedirs("%d/%d" % (zoom, i), exist_ok=True)
# fname = "%d/%d/%d.png" % (zoom, i, j)
# if not matplotlib.path.Path(numpy.array(polygon)).intersects_bbox(
# matplotlib.transforms.Bbox(
# [
# (i * TILESIZE, j * TILESIZE),
# (
# (i + 1) * TILESIZE,
# (j + 1) * TILESIZE,
# ),
# ]
# )
# ):
# continue
# if not os.path.exists(fname):
# todl.append((i, j))
#for n, (i, j) in enumerate(todl):
# print("%d/%d" % (n, len(todl)))
# fname = "%d/%d/%d.png" % (zoom, i, j)
# urllib.request.urlretrieve(
# #"https://tile.openstreetmap.org/%d/%d/%d.png" % (zoom, i, j),
# #https://a.tile.thunderforest.com/cycle/17/68690/44518.png?apikey=6170aad10dfd42a38d4d8c709a53
# "https://tile.thunderforest.com/cycle/%d/%d/%d.png?apikey=d8f470ce7a8e4dd0acf39cc8fd3cf979" % (zoom, i, j),
# #"https://tile.thunderforest.com/outdoors/%d/%d/%d.png?apikey=d8f470ce7a8e4dd0acf39cc8fd3cf979" % (zoom, i, j),
# #"https://tile.thunderforest.com/landscape/%d/%d/%d.png?apikey=d8f470ce7a8e4dd0acf39cc8fd3cf979" % (zoom, i, j),
# #"https://tile.thunderforest.com/atlas/%d/%d/%d.png?apikey=d8f470ce7a8e4dd0acf39cc8fd3cf979" % (zoom, i, j),
# filename=fname,
# )
#for i in range(int(minx / TILESIZE) - 1, int(maxx / TILESIZE) + 2):
# for j in range(int(miny / TILESIZE) - 1, int(maxy / TILESIZE) + 2):
# if not matplotlib.path.Path(numpy.array(polygon)).intersects_bbox(
# matplotlib.transforms.Bbox(
# [
# (i * TILESIZE, j * TILESIZE),
# (
# (i + 1) * TILESIZE,
# (j + 1) * TILESIZE,
# ),
# ]
# )
# ):
# continue
# fname = "%d/%d/%d.png" % (zoom, i, j)
# with Image.open(fname) as tile:
# im1.paste(tile, (int(i * TILESIZE - minx), int(j * TILESIZE - miny)))
# im2.paste(tile, (int(i * TILESIZE - minx), int(j * TILESIZE - miny)))
#draw2 = ImageDraw.Draw(im2)
#draw2.line([(xi - minx, yi - miny) for xi, yi in path], fill=(255, 0, 0), width=4)
#draw1 = ImageDraw.Draw(im1)
#draw1.line([(xi - minx, yi - miny) for xi, yi in path], fill=(255, 0, 0), width=4)
#draw1.line([(xi - minx, yi - miny) for xi, yi in zip(*out)], fill=(0, 255, 0))
#for ((p00, p01), (p10, p11), (p20, p21), (p30, p31)) in quads:
# draw1.polygon(
# [
# (p00 - minx, p01 - miny),
# (p10 - minx, p11 - miny),
# (p20 - minx, p21 - miny),
# (p30 - minx, p31 - miny),
# ]
# )
#draw1.polygon([(xi - minx, yi - miny) for xi, yi in polygon], outline=(0, 0, 255))
#im1.save("out2.png")
#data = []
#for i, (off, h, (p0, p1, p2, p3)) in enumerate(zip(offs, heights, quads)):
# data.append(
# (
# (
# 0,
# int(height - offs[i] - heights[i]),
# int(width),
# int(height - offs[i]),
# ),
# (
# p0[0] - minx,
# p0[1] - miny,
# p1[0] - minx,
# p1[1] - miny,
# p2[0] - minx,
# p2[1] - miny,
# p3[0] - minx,
# p3[1] - miny,
# ),
# )
# )
#im_out = im2.transform(
# (int(width), int(height)),
# Image.MESH,
# data,
# Image.BICUBIC,
#)
#im_out.save("out.png")
#im_out.save("out.jpg", quality=95)
#return True
if __name__ == "__main__":
main()