Mario Voigt
4175b377bd
's/fablabchemnitz_//g' *.inx;sed -i 's/>fablabchemnitz_/>/g' *.inx;sed -i 's/fablabchemnitz_//g' *.py; rename 's/fablabchemnitz_//g' *.svg"
380 lines
14 KiB
Python
380 lines
14 KiB
Python
#!/usr/bin/env python3
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# Copyright (c) 2012-2018 Tobias Leupold <tobias.leupold@gmx.de>
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#
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# gpx2svg - Convert GPX formatted geodata to Scalable Vector Graphics (SVG)
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#
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# This program is free software; you can redistribute it and/or modify it
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# under the terms of the GNU General Public License as published by the Free
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# Software Foundation in version 2 of the License.
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#
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# This program is distributed in the hope that it will be useful, but
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# WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
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# or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
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# for more details.
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#
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# You should have received a copy of the GNU General Public License along
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# with this program; if not, write to the Free Software Foundation, Inc.,
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# 59 Temple Place, Suite 330, Boston, MA 02111-1307, USA.
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#
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# modified by monomono@disroot.org at 2019-08-05 for use on inkscape extension,
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# 3to2 python converter and adjust parser_options for inkscape compatibility.
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from __future__ import division
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from __future__ import absolute_import
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from io import open
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__version__ = u'@VERSION@'
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import argparse
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import sys
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import math
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from xml.dom.minidom import parse as parseXml
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from os.path import abspath
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def parseGpx(gpxFile):
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u"""Get the latitude and longitude data of all track segments in a GPX file"""
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if gpxFile == u'/dev/stdin':
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gpxFile = sys.stdin
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# Get the XML information
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try:
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gpx = parseXml(gpxFile)
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except IOError as error:
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print (sys.stderr, u'Error while reading file: {}. Terminating.'.format(error))
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sys.exit(1)
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except:
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print (sys.stderr, u'Error while parsing XML data:')
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print (sys.stderr, sys.exc_info())
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print (sys.stderr, u'Terminating.')
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sys.exit(1)
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# Iterate over all tracks, track segments and points
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gpsData = []
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for track in gpx.getElementsByTagName(u'trk'):
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for trackseg in track.getElementsByTagName(u'trkseg'):
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trackSegData = []
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for point in trackseg.getElementsByTagName(u'trkpt'):
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trackSegData.append(
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(float(point.attributes[u'lon'].value), float(point.attributes[u'lat'].value))
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)
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# Leave out empty segments
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if(trackSegData != []):
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gpsData.append(trackSegData)
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return gpsData
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def calcProjection(gpsData):
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u"""Calculate a plane projection for a GPS dataset"""
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projectedData = []
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for segment in gpsData:
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projectedSegment = []
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for coord in segment:
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# At the moment, we only have the Mercator projection
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projectedSegment.append(mercatorProjection(coord))
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projectedData.append(projectedSegment)
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return projectedData
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def mercatorProjection(coord):
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u"""Calculate the Mercator projection of a coordinate pair"""
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# Assuming we're on earth, we have (according to GRS 80):
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r = 6378137.0
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# As long as meridian = 0 and can't be changed, we don't need:
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# meridian = meridian * math.pi / 180.0
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# x = r * ((coord[0] * math.pi / 180.0) - meridian)
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# Instead, we use this simplified version:
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x = r * coord[0] * math.pi / 180.0
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y = r * math.log(math.tan((math.pi / 4.0) + ((coord[1] * math.pi / 180.0) / 2.0)))
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return x, y
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def moveProjectedData(gpsData):
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u"""Move a dataset to 0,0 and return it with the resulting width and height"""
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# Find the minimum and maximum x and y coordinates
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minX = maxX = gpsData[0][0][0]
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minY = maxY = gpsData[0][0][1]
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for segment in gpsData:
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for coord in segment:
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if coord[0] < minX:
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minX = coord[0]
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if coord[0] > maxX:
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maxX = coord[0]
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if coord[1] < minY:
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minY = coord[1]
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if coord[1] > maxY:
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maxY = coord[1]
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# Move the GPS data to 0,0
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movedGpsData = []
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for segment in gpsData:
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movedSegment = []
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for coord in segment:
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movedSegment.append((coord[0] - minX, coord[1] - minY))
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movedGpsData.append(movedSegment)
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# Return the moved data and it's width and height
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return movedGpsData, maxX - minX, maxY - minY
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def searchCircularSegments(gpsData):
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u"""Splits a GPS dataset to tracks that are circular and other tracks"""
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circularSegments = []
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straightSegments = []
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for segment in gpsData:
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if segment[0] == segment[len(segment) - 1]:
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circularSegments.append(segment)
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else:
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straightSegments.append(segment)
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return circularSegments, straightSegments
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def combineSegmentPairs(gpsData):
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u"""Combine segment pairs to one bigger segment"""
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combinedData = []
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# Walk through the GPS data and search for segment pairs
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# that end with the starting point of another track
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while len(gpsData) > 0:
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# Get one segment from the source GPS data
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firstTrackData = gpsData.pop()
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foundMatch = False
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# Try to find a matching segment
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for i in xrange(len(gpsData)):
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if firstTrackData[len(firstTrackData) - 1] == gpsData[i][0]:
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# There is a matching segment, so break here
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foundMatch = True
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break
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if foundMatch == True:
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# We found a pair of segments with one shared point, so pop the data of the second
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# segment from the source GPS data and create a new segment containing all data, but
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# without the overlapping point
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firstTrackData.pop()
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combinedData.append(firstTrackData + gpsData[i])
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gpsData.pop(i)
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else:
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# No segment with a shared point was found, so just append the data to the output
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combinedData.append(firstTrackData)
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return searchCircularSegments(combinedData)
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def combineSegments(gpsData):
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u"""Combine all segments of a GPS dataset that can be combined"""
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# Search for circular segments. We can't combine them with any other segment.
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circularSegments, remainingSegments = searchCircularSegments(gpsData)
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# Search for segments that can be combined
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while True:
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# Look how many tracks we have now
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segmentsBefore = len(remainingSegments)
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# Search for segments that can be combined
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newCircularSegments, remainingSegments = combineSegmentPairs(remainingSegments)
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# Add newly found circular segments to processedSegments -- they can't be used anymore
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circularSegments = circularSegments + newCircularSegments
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if segmentsBefore == len(remainingSegments):
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# combineSegmentPairs() did not reduce the number of tracks anymore,
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# so we can't combine more tracks and can stop here
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break
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return circularSegments + remainingSegments
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def chronologyJoinSegments(gpsData):
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u"""Join all segments to a big one in the order defined by the GPX file."""
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joinedSegment = []
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for segment in gpsData:
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joinedSegment += segment
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return [joinedSegment]
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def scaleCoords(coord, height, scale):
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u"""Return a scaled pair of coordinates"""
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return coord[0] * scale, (coord[1] * -1 + height) * scale
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def generateScaledSegment(segment, height, scale):
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u"""Create the coordinate part of an SVG path string from a GPS data segment"""
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for coord in segment:
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yield scaleCoords(coord, height, scale)
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def writeSvgData(gpsData, width, height, maxPixels, dropSinglePoints, outfile):
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u"""Output the SVG data -- quick 'n' dirty, without messing around with dom stuff ;-)"""
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# Calculate the scale factor we need to fit the requested maximal output size
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if width <= maxPixels and height <= maxPixels:
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scale = 1
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elif width > height:
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scale = maxPixels / width
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else:
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scale = maxPixels / height
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# Open the requested output file or map to /dev/stdout
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if outfile != u'/dev/stdout':
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try:
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fp = open(outfile, u'w')
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except IOError as error:
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print (sys.stderr, u"Can't open output file: {}. Terminating.".format(error))
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sys.exit(1)
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else:
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fp = sys.stdout
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# Header data
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fp.write( u'<?xml version="1.0" encoding="UTF-8" standalone="no"?>\n')
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fp.write((u'<!DOCTYPE svg PUBLIC "-//W3C//DTD SVG 1.1//EN" '
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u'"http://www.w3.org/Graphics/SVG/1.1/DTD/svg11.dtd">\n'))
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fp.write( u'<!-- Created with gpx2svg {} -->\n'.format(__version__))
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fp.write((u'<svg xmlns="http://www.w3.org/2000/svg" version="1.1" '
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u'width="{}px" height="{}px">\n').format(width * scale, height * scale))
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# Process all track segments and generate ids and path drawing commands for them
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# First, we split the data to circular and straight segments
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circularSegments, straightSegments = searchCircularSegments(gpsData)
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realCircularSegments = []
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singlePoints = []
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for segment in circularSegments:
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# We can leave out the last point, because it's equal to the first one
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segment.pop()
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if len(segment) == 1:
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# It's a single point
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if dropSinglePoints == False:
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# We want to keep single points, so add it to singlePoints
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singlePoints.append(segment)
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else:
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realCircularSegments.append(segment)
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circularSegments = realCircularSegments
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# Draw single points if requested
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if len(singlePoints) > 0:
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fp.write(u'<g>\n')
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for segment in singlePoints:
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x, y = scaleCoords(segment[0], height, scale)
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fp.write(
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u'<circle cx="{}" cy="{}" r="0.5" style="stroke:none;fill:black"/>\n'.format(x, y)
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)
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fp.write(u'</g>\n')
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# Draw all circular segments
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if len(circularSegments) > 0:
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fp.write(u'<g>\n')
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for segment in circularSegments:
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fp.write(u'<path d="M')
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for x, y in generateScaledSegment(segment, height, scale):
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fp.write(u' {} {}'.format(x, y))
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fp.write(u' Z" style="fill:none;stroke:black"/>\n')
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fp.write(u'</g>\n')
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# Draw all un-closed paths
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if len(straightSegments) > 0:
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fp.write(u'<g>\n')
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for segment in straightSegments:
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fp.write(u'<path d="M')
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for x, y in generateScaledSegment(segment, height, scale):
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fp.write(u' {} {}'.format(x, y))
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fp.write(u'" style="fill:none;stroke:black"/>\n')
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fp.write(u'</g>\n')
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# Close the XML
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fp.write(u'</svg>\n')
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# Close the file if necessary
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if fp != sys.stdout:
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fp.close()
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def main():
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# Setup the command line argument parser
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cmdArgParser = argparse.ArgumentParser(
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description = u'Convert GPX formatted geodata to Scalable Vector Graphics (SVG)',
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epilog = u'gpx2svg {} - http://nasauber.de/opensource/gpx2svg/'.format(__version__)
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)
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cmdArgParser.add_argument(
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u'i', metavar = u'FILE', nargs = u'?', default = u'/dev/stdin',
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help = u'GPX input file (default: read from STDIN)'
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)
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cmdArgParser.add_argument(
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u'--o', metavar = u'FILE', nargs = u'?', default = u'/dev/stdout',
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help = u'SVG output file (default: write to STDOUT)'
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)
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cmdArgParser.add_argument(
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u'--m', metavar = u'PIXELS', nargs = u'?', type = int, default = 3000,
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help = u'Maximum width or height of the SVG output in pixels (default: 3000)'
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)
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cmdArgParser.add_argument(
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u'--d',
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help = u'Drop single points (default: draw a circle with 1px diameter)'
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)
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cmdArgParser.add_argument(
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u'--r',
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help = (u'"Raw" conversion: Create one SVG path per track segment, don\'t try to combine '
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u'paths that end with the starting point of another path')
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)
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cmdArgParser.add_argument(
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u'--j',
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help = (u'Join all segments to a big one in the order of the GPX file. This can create an '
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u'un-scattered path if the default combining algorithm does not work because there '
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u'are no matching points across segments (implies -r)')
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)
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cmdArgParser.add_argument(
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u'--tab',
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help = (u'inkscape option')
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)
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# Get the given arguments
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cmdArgs = cmdArgParser.parse_args()
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# Map "-" to STDIN or STDOUT
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if cmdArgs.i == u'-':
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cmdArgs.i = u'/dev/stdin'
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if cmdArgs.o == u'-':
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cmdArgs.o = u'/dev/stdout'
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# Check if a given input or output file name is a relative representation of STDIN or STDOUT
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if cmdArgs.i != u'/dev/stdin':
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if abspath(cmdArgs.i) == u'/dev/stdin':
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cmdArgs.i = u'/dev/stdin'
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if cmdArgs.o != u'/dev/stdout':
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if abspath(cmdArgs.o) == u'/dev/stdout':
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cmdArgs.o = u'/dev/stdout'
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# Get the latitude and longitude data from the given GPX file or STDIN
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gpsData = parseGpx(cmdArgs.i)
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# Check if we actually _have_ data
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if gpsData == []:
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print (sys.stderr, u'No data to convert. Terminating.')
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sys.exit(1)
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# Join all segments if requested by "-j"
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if bool(cmdArgs.j):
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gpsData = chronologyJoinSegments(gpsData)
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# Try to combine all track segments that can be combined if not requested otherwise
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# Don't execute if all segments are already joined with "-j"
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if not bool(cmdArgs.r) and not bool(cmdArgs.j):
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gpsData = combineSegments(gpsData)
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# Calculate a plane projection for a GPS dataset
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# At the moment, we only have the Mercator projection
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gpsData = calcProjection(gpsData)
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# Move the projected data to the 0,0 origin of a cartesial coordinate system
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# and get the raw width and height of the resulting vector data
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gpsData, width, height = moveProjectedData(gpsData)
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# Write the resulting SVG data to the requested output file or STDOUT
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writeSvgData(gpsData, width, height, cmdArgs.m, bool(cmdArgs.d), cmdArgs.o)
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if __name__ == u'__main__':
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main()
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