642 lines
29 KiB
Python
642 lines
29 KiB
Python
#!/usr/bin/env python3
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'''
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Generates Inkscape SVG file containing box components needed to
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laser cut a tabbed construction box taking kerf and clearance into account
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Copyright (C) 2011 elliot white
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Changelog:
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19/12/2014 Paul Hutchison:
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- Ability to generate 6, 5, 4, 3 or 2-panel cutouts
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- Ability to also generate evenly spaced dividers within the box
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including tabbed joints to box sides and slots to slot into each other
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23/06/2015 by Paul Hutchison:
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- Updated for Inkscape's 0.91 breaking change (unittouu)
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v0.93 - 15/8/2016 by Paul Hutchison:
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- Added Hairline option and fixed open box height bug
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v0.94 - 05/01/2017 by Paul Hutchison:
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- Added option for keying dividers into walls/floor/none
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v0.95 - 2017-04-20 by Jim McBeath
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- Added optional dimples
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v0.96 - 2017-04-24 by Jim McBeath
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- Refactored to make box type, tab style, and layout all orthogonal
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- Added Tab Style option to allow creating waffle-block-style tabs
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- Made open box size correct based on inner or outer dimension choice
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- Fixed a few tab bugs
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v0.99 - 2020-06-01 by Paul Hutchison
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- Preparatory release with Inkscape 1.0 compatibility upgrades (further fixes to come!)
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- Removed Antisymmetric option as it's broken, kinda pointless and looks weird
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- Fixed divider issues with Rotate Symmetric
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- Made individual panels and their keyholes/slots grouped
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This program is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <http://www.gnu.org/licenses/>.
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'''
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__version__ = "0.99" ### please report bugs, suggestions etc at https://github.com/paulh-rnd/TabbedBoxMaker ###
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import os
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import inkex
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import gettext
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import math
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from copy import deepcopy
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_ = gettext.gettext
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linethickness = 1 # default unless overridden by settings
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def log(text):
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if 'SCHROFF_LOG' in os.environ:
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f = open(os.environ.get('SCHROFF_LOG'), 'a')
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f.write(text + "\n")
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def newGroup(canvas):
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# Create a new group and add element created from line string
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panelId = canvas.svg.get_unique_id('panel')
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group = canvas.svg.get_current_layer().add(inkex.Group(id=panelId))
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return group
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def getLine(XYstring):
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line = inkex.PathElement()
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line.style = { 'stroke': '#000000', 'stroke-width' : str(linethickness), 'fill': 'none' }
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line.path = XYstring
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#inkex.etree.SubElement(parent, inkex.addNS('path','svg'), drw)
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return line
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# jslee - shamelessly adapted from sample code on below Inkscape wiki page 2015-07-28
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# http://wiki.inkscape.org/wiki/index.php/Generating_objects_from_extensions
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def getCircle(r, c):
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(cx, cy) = c
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log("putting circle at (%d,%d)" % (cx,cy))
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circle = inkex.PathElement.arc((cx, cy), r)
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circle.style = { 'stroke': '#000000', 'stroke-width': str(linethickness), 'fill': 'none' }
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return circle
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def dimpleStr(tabVector,vectorX,vectorY,directionX,directionY,dirxN,diryN,ddir,isTab):
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ds=''
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if not isTab:
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ddir = -ddir
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if dimpleHeight>0 and tabVector!=0:
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if tabVector>0:
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dimpleStart=(tabVector-dimpleLength)/2-dimpleHeight
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tabSgn=1
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else:
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dimpleStart=(tabVector+dimpleLength)/2+dimpleHeight
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tabSgn=-1
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Vxd=vectorX+dirxN*dimpleStart
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Vyd=vectorY+diryN*dimpleStart
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ds+='L '+str(Vxd)+','+str(Vyd)+' '
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Vxd=Vxd+(tabSgn*dirxN-ddir*directionX)*dimpleHeight
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Vyd=Vyd+(tabSgn*diryN-ddir*directionY)*dimpleHeight
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ds+='L '+str(Vxd)+','+str(Vyd)+' '
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Vxd=Vxd+tabSgn*dirxN*dimpleLength
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Vyd=Vyd+tabSgn*diryN*dimpleLength
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ds+='L '+str(Vxd)+','+str(Vyd)+' '
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Vxd=Vxd+(tabSgn*dirxN+ddir*directionX)*dimpleHeight
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Vyd=Vyd+(tabSgn*diryN+ddir*directionY)*dimpleHeight
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ds+='L '+str(Vxd)+','+str(Vyd)+' '
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return ds
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def side(group,root,startOffset,endOffset,tabVec,length,direction,isTab,isDivider,numDividers,dividerSpacing):
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rootX, rootY = root
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startOffsetX, startOffsetY = startOffset
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endOffsetX, endOffsetY = endOffset
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directionX, directionY = direction
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if (tabSymmetry==1): # waffle-block style rotationally symmetric tabs
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divisions=int((length-2*thickness)/nomTab)
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if divisions%2: divisions+=1 # make divs even
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divisions=float(divisions)
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tabs=divisions/2 # tabs for side
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else:
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divisions=int(length/nomTab)
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if not divisions%2: divisions-=1 # make divs odd
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divisions=float(divisions)
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tabs=(divisions-1)/2 # tabs for side
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if (tabSymmetry==1): # waffle-block style rotationally symmetric tabs
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gapWidth=tabWidth=(length-2*thickness)/divisions
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elif equalTabs:
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gapWidth=tabWidth=length/divisions
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else:
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tabWidth=nomTab
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gapWidth=(length-tabs*nomTab)/(divisions-tabs)
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if isTab: # kerf correction
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gapWidth-=correction
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tabWidth+=correction
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first=correction/2
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else:
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gapWidth+=correction
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tabWidth-=correction
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first=-correction/2
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s=[]
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h=[]
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firstVec=0; secondVec=tabVec
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dividerEdgeOffsetX = dividerEdgeOffsetY = thickness
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dirxN=0 if directionX else 1 # used to select operation on x or y
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diryN=0 if directionY else 1
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if (tabSymmetry==1):
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dividerEdgeOffsetX = directionX*thickness;
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#dividerEdgeOffsetY = ;
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vectorX = rootX + (startOffsetX*thickness if dirxN else 0)
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vectorY = rootY + (startOffsetY*thickness if diryN else 0)
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s='M '+str(vectorX)+','+str(vectorY)+' '
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vectorX = rootX+(startOffsetX if startOffsetX else directionX)*thickness
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vectorY = rootY+(startOffsetY if startOffsetY else directionY)*thickness
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if dirxN: endOffsetX=0
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if diryN: endOffsetY=0
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else:
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(vectorX,vectorY)=(rootX+startOffsetX*thickness,rootY+startOffsetY*thickness)
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dividerEdgeOffsetX=directionY*thickness
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dividerEdgeOffsetY=directionX*thickness
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s='M '+str(vectorX)+','+str(vectorY)+' '
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if dirxN: vectorY=rootY # set correct line start for tab generation
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if diryN: vectorX=rootX
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# generate line as tab or hole using:
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# last co-ord:Vx,Vy ; tab dir:tabVec ; direction:dirx,diry ; thickness:thickness
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# divisions:divs ; gap width:gapWidth ; tab width:tabWidth
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for n in range(1,int(divisions)):
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if ((n%2) ^ (not isTab)) and numDividers>0 and not isDivider: # draw holes for divider joints in side walls
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w=gapWidth if isTab else tabWidth
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if n==1 and tabSymmetry==0:
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w-=startOffsetX*thickness
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for m in range(1,int(numDividers)+1):
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Dx=vectorX+-directionY*dividerSpacing*m
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Dy=vectorY+directionX*dividerSpacing*m
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if n==1 and tabSymmetry==0:
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Dx+=startOffsetX*thickness
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h='M '+str(Dx)+','+str(Dy)+' '
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Dx=Dx+directionX*w+dirxN*firstVec+first*directionX
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Dy=Dy+directionY*w+diryN*firstVec+first*directionY
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h+='L '+str(Dx)+','+str(Dy)+' '
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Dx=Dx+dirxN*secondVec
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Dy=Dy+diryN*secondVec
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h+='L '+str(Dx)+','+str(Dy)+' '
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Dx=Dx-(directionX*w+dirxN*firstVec+first*directionX)
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Dy=Dy-(directionY*w+diryN*firstVec+first*directionY)
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h+='L '+str(Dx)+','+str(Dy)+' '
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Dx=Dx-dirxN*secondVec
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Dy=Dy-diryN*secondVec
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h+='L '+str(Dx)+','+str(Dy)+' '
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group.add(getLine(h))
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if n%2:
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if n==1 and numDividers>0 and isDivider: # draw slots for dividers to slot into each other
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for m in range(1,int(numDividers)+1):
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Dx=vectorX+-directionY*dividerSpacing*m-dividerEdgeOffsetX
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Dy=vectorY+directionX*dividerSpacing*m-dividerEdgeOffsetY
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h='M '+str(Dx)+','+str(Dy)+' '
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Dx=Dx+directionX*(first+length/2)
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Dy=Dy+directionY*(first+length/2)
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h+='L '+str(Dx)+','+str(Dy)+' '
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Dx=Dx+dirxN*thickness
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Dy=Dy+diryN*thickness
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h+='L '+str(Dx)+','+str(Dy)+' '
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Dx=Dx-directionX*(first+length/2)
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Dy=Dy-directionY*(first+length/2)
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h+='L '+str(Dx)+','+str(Dy)+' '
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Dx=Dx-dirxN*thickness
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Dy=Dy-diryN*thickness
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h+='L '+str(Dx)+','+str(Dy)+' '
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group.add(getLine(h))
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# draw the gap
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vectorX=vectorX+directionX*gapWidth+dirxN*firstVec+first*directionX
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vectorY=vectorY+directionY*gapWidth+diryN*firstVec+first*directionY
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s+='L '+str(vectorX)+','+str(vectorY)+' '
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# draw the starting edge of the tab
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s+=dimpleStr(secondVec,vectorX,vectorY,directionX,directionY,dirxN,diryN,1,isTab)
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vectorX=vectorX+dirxN*secondVec
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vectorY=vectorY+diryN*secondVec
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s+='L '+str(vectorX)+','+str(vectorY)+' '
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else:
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# draw the tab
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vectorX=vectorX+directionX*tabWidth+dirxN*firstVec
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vectorY=vectorY+directionY*tabWidth+diryN*firstVec
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s+='L '+str(vectorX)+','+str(vectorY)+' '
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# draw the ending edge of the tab
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s+=dimpleStr(secondVec,vectorX,vectorY,directionX,directionY,dirxN,diryN,-1,isTab)
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vectorX=vectorX+dirxN*secondVec
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vectorY=vectorY+diryN*secondVec
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s+='L '+str(vectorX)+','+str(vectorY)+' '
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(secondVec,firstVec)=(-secondVec,-firstVec) # swap tab direction
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first=0
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#finish the line off
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s+='L '+str(rootX+endOffsetX*thickness+directionX*length)+','+str(rootY+endOffsetY*thickness+directionY*length)+' '
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if isTab and numDividers>0 and tabSymmetry==0 and not isDivider: # draw last for divider joints in side walls
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for m in range(1,int(numDividers)+1):
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Dx=vectorX
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Dy=vectorY+directionX*dividerSpacing*m
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h='M '+str(Dx)+','+str(Dy)+' '
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Dx=rootX+endOffsetX*thickness+directionX*length
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Dy=Dy+directionY*tabWidth+diryN*firstVec+first*directionY
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h+='L '+str(Dx)+','+str(Dy)+' '
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Dx=Dx+dirxN*secondVec
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Dy=Dy+diryN*secondVec
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h+='L '+str(Dx)+','+str(Dy)+' '
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Dx=vectorX
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Dy=Dy-(directionY*tabWidth+diryN*firstVec+first*directionY)
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h+='L '+str(Dx)+','+str(Dy)+' '
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Dx=Dx-dirxN*secondVec
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Dy=Dy-diryN*secondVec
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h+='L '+str(Dx)+','+str(Dy)+' '
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group.add(getLine(h))
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group.add(getLine(s))
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return s
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class BoxMaker(inkex.Effect):
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def __init__(self):
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# Call the base class constructor.
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inkex.Effect.__init__(self)
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# Define options
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self.arg_parser.add_argument('--schroff',type=int,default=0,help='Enable Schroff mode')
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self.arg_parser.add_argument('--rail_height',type=float,default=10.0,help='Height of rail')
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self.arg_parser.add_argument('--rail_mount_depth',type=float,default=17.4,help='Depth at which to place hole for rail mount bolt')
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self.arg_parser.add_argument('--rail_mount_centre_offset',type=float, default=0.0,help='How far toward row centreline to offset rail mount bolt (from rail centreline)')
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self.arg_parser.add_argument('--rows',type=int,default=0,help='Number of Schroff rows')
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self.arg_parser.add_argument('--hp',type=int,default=0,help='Width (TE/HP units) of Schroff rows')
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self.arg_parser.add_argument('--row_spacing',type=float,default=10.0,help='Height of rail')
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self.arg_parser.add_argument('--unit', default='mm',help='Measure Units')
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self.arg_parser.add_argument('--inside',type=int,default=0,help='Int/Ext Dimension')
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self.arg_parser.add_argument('--length',type=float,default=100,help='Length of Box')
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self.arg_parser.add_argument('--width',type=float,default=100,help='Width of Box')
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self.arg_parser.add_argument('--depth',type=float,default=100,help='Height of Box')
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self.arg_parser.add_argument('--tab',type=float,default=25,help='Nominal Tab Width')
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self.arg_parser.add_argument('--equal',type=int,default=0,help='Equal/Prop Tabs')
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self.arg_parser.add_argument('--tabsymmetry',type=int,default=0,help='Tab style')
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self.arg_parser.add_argument('--dimpleheight',type=float,default=0,help='Tab Dimple Height')
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self.arg_parser.add_argument('--dimplelength',type=float,default=0,help='Tab Dimple Tip Length')
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self.arg_parser.add_argument('--hairline',type=int,default=0,help='Line Thickness')
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self.arg_parser.add_argument('--thickness',type=float,default=10,help='Thickness of Material')
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self.arg_parser.add_argument('--kerf',type=float,default=0.5,help='Kerf (width) of cut')
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self.arg_parser.add_argument('--clearance',type=float,default=0.01,help='Clearance of joints')
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self.arg_parser.add_argument('--style',type=int,default=25,help='Layout/Style')
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self.arg_parser.add_argument('--spacing',type=float,default=25,help='Part Spacing')
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self.arg_parser.add_argument('--boxtype',type=int,default=25,help='Box type')
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self.arg_parser.add_argument('--div_l',type=int,default=25,help='Dividers (Length axis)')
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self.arg_parser.add_argument('--div_w',type=int,default=25,help='Dividers (Width axis)')
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self.arg_parser.add_argument('--keydiv',type=int,default=3,help='Key dividers into walls/floor')
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def effect(self):
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global group,nomTab,equalTabs,tabSymmetry,dimpleHeight,dimpleLength,thickness,correction,divx,divy,hairline,linethickness,keydivwalls,keydivfloor
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# Get access to main SVG document element and get its dimensions.
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svg = self.document.getroot()
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# Get the attributes:
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widthDoc = self.svg.unittouu(svg.get('width'))
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heightDoc = self.svg.unittouu(svg.get('height'))
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# Get script's option values.
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hairline=self.options.hairline
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unit=self.options.unit
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inside=self.options.inside
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schroff=self.options.schroff
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# Set the line thickness
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if hairline:
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linethickness=self.svg.unittouu('0.002in')
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else:
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linethickness=1
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if schroff:
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rows=self.options.rows
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rail_height=self.svg.unittouu(str(self.options.rail_height)+unit)
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row_centre_spacing=self.svg.unittouu(str(122.5)+unit)
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row_spacing=self.svg.unittouu(str(self.options.row_spacing)+unit)
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rail_mount_depth=self.svg.unittouu(str(self.options.rail_mount_depth)+unit)
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rail_mount_centre_offset=self.svg.unittouu(str(self.options.rail_mount_centre_offset)+unit)
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rail_mount_radius=self.svg.unittouu(str(2.5)+unit)
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## minimally different behaviour for schroffmaker.inx vs. boxmaker.inx
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## essentially schroffmaker.inx is just an alternate interface with different
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## default settings, some options removed, and a tiny amount of extra logic
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if schroff:
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## schroffmaker.inx
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X = self.svg.unittouu(str(self.options.hp * 5.08) + unit)
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# 122.5mm vertical distance between mounting hole centres of 3U Schroff panels
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row_height = rows * (row_centre_spacing + rail_height)
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# rail spacing in between rows but never between rows and case panels
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row_spacing_total = (rows - 1) * row_spacing
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Y = row_height + row_spacing_total
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else:
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## boxmaker.inx
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X = self.svg.unittouu( str(self.options.length) + unit )
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Y = self.svg.unittouu( str(self.options.width) + unit )
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Z = self.svg.unittouu( str(self.options.rail_height) + unit )
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thickness = self.svg.unittouu( str(self.options.thickness) + unit )
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nomTab = self.svg.unittouu( str(self.options.tab) + unit )
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equalTabs=self.options.equal
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tabSymmetry=self.options.tabsymmetry
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dimpleHeight=self.options.dimpleheight
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dimpleLength=self.options.dimplelength
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kerf = self.svg.unittouu( str(self.options.kerf) + unit )
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clearance = self.svg.unittouu( str(self.options.clearance) + unit )
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layout=self.options.style
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spacing = self.svg.unittouu( str(self.options.spacing) + unit )
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boxtype = self.options.boxtype
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divx = self.options.div_l
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divy = self.options.div_w
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keydivwalls = 0 if self.options.keydiv == 3 or self.options.keydiv == 1 else 1
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keydivfloor = 0 if self.options.keydiv == 3 or self.options.keydiv == 2 else 1
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if inside: # if inside dimension selected correct values to outside dimension
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X+=thickness*2
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Y+=thickness*2
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Z+=thickness*2
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correction=kerf-clearance
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# check input values mainly to avoid python errors
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# TODO restrict values to *correct* solutions
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# TODO restrict divisions to logical values
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error=0
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if min(X,Y,Z)==0:
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inkex.errormsg(_('Error: Dimensions must be non zero'))
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error=1
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if max(X,Y,Z)>max(widthDoc,heightDoc)*10: # crude test
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inkex.errormsg(_('Error: Dimensions Too Large'))
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error=1
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if min(X,Y,Z)<3*nomTab:
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inkex.errormsg(_('Error: Tab size too large'))
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error=1
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if nomTab<thickness:
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inkex.errormsg(_('Error: Tab size too small'))
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error=1
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if thickness==0:
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inkex.errormsg(_('Error: Thickness is zero'))
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error=1
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|
if thickness>min(X,Y,Z)/3: # crude test
|
|
inkex.errormsg(_('Error: Material too thick'))
|
|
error=1
|
|
if correction>min(X,Y,Z)/3: # crude test
|
|
inkex.errormsg(_('Error: Kerf/Clearence too large'))
|
|
error=1
|
|
if spacing>max(X,Y,Z)*10: # crude test
|
|
inkex.errormsg(_('Error: Spacing too large'))
|
|
error=1
|
|
if spacing<kerf:
|
|
inkex.errormsg(_('Error: Spacing too small'))
|
|
error=1
|
|
|
|
if error: exit()
|
|
|
|
# For code spacing consistency, we use two-character abbreviations for the six box faces,
|
|
# where each abbreviation is the first and last letter of the face name:
|
|
# tp=top, bm=bottom, ft=front, bk=back, lt=left, rt=right
|
|
|
|
# Determine which faces the box has based on the box type
|
|
hasTp=hasBm=hasFt=hasBk=hasLt=hasRt = True
|
|
if boxtype==2: hasTp=False
|
|
elif boxtype==3: hasTp=hasFt=False
|
|
elif boxtype==4: hasTp=hasFt=hasRt=False
|
|
elif boxtype==5: hasTp=hasBm=False
|
|
elif boxtype==6: hasTp=hasFt=hasBk=hasRt=False
|
|
# else boxtype==1, full box, has all sides
|
|
|
|
# Determine where the tabs go based on the tab style
|
|
if tabSymmetry==2: # Antisymmetric (deprecated)
|
|
tpTabInfo=0b0110
|
|
bmTabInfo=0b1100
|
|
ltTabInfo=0b1100
|
|
rtTabInfo=0b0110
|
|
ftTabInfo=0b1100
|
|
bkTabInfo=0b1001
|
|
elif tabSymmetry==1: # Rotationally symmetric (Waffle-blocks)
|
|
tpTabInfo=0b1111
|
|
bmTabInfo=0b1111
|
|
ltTabInfo=0b1111
|
|
rtTabInfo=0b1111
|
|
ftTabInfo=0b1111
|
|
bkTabInfo=0b1111
|
|
else: # XY symmetric
|
|
tpTabInfo=0b0000
|
|
bmTabInfo=0b0000
|
|
ltTabInfo=0b1111
|
|
rtTabInfo=0b1111
|
|
ftTabInfo=0b1010
|
|
bkTabInfo=0b1010
|
|
|
|
def fixTabBits(tabbed, tabInfo, bit):
|
|
newTabbed = tabbed & ~bit
|
|
if inside:
|
|
newTabInfo = tabInfo | bit # set bit to 1 to use tab base line
|
|
else:
|
|
newTabInfo = tabInfo & ~bit # set bit to 0 to use tab tip line
|
|
return newTabbed, newTabInfo
|
|
|
|
# Update the tab bits based on which sides of the box don't exist
|
|
tpTabbed=bmTabbed=ltTabbed=rtTabbed=ftTabbed=bkTabbed=0b1111
|
|
if not hasTp:
|
|
bkTabbed, bkTabInfo = fixTabBits(bkTabbed, bkTabInfo, 0b0010)
|
|
ftTabbed, ftTabInfo = fixTabBits(ftTabbed, ftTabInfo, 0b1000)
|
|
ltTabbed, ltTabInfo = fixTabBits(ltTabbed, ltTabInfo, 0b0001)
|
|
rtTabbed, rtTabInfo = fixTabBits(rtTabbed, rtTabInfo, 0b0100)
|
|
tpTabbed=0
|
|
if not hasBm:
|
|
bkTabbed, bkTabInfo = fixTabBits(bkTabbed, bkTabInfo, 0b1000)
|
|
ftTabbed, ftTabInfo = fixTabBits(ftTabbed, ftTabInfo, 0b0010)
|
|
ltTabbed, ltTabInfo = fixTabBits(ltTabbed, ltTabInfo, 0b0100)
|
|
rtTabbed, rtTabInfo = fixTabBits(rtTabbed, rtTabInfo, 0b0001)
|
|
bmTabbed=0
|
|
if not hasFt:
|
|
tpTabbed, tpTabInfo = fixTabBits(tpTabbed, tpTabInfo, 0b1000)
|
|
bmTabbed, bmTabInfo = fixTabBits(bmTabbed, bmTabInfo, 0b1000)
|
|
ltTabbed, ltTabInfo = fixTabBits(ltTabbed, ltTabInfo, 0b1000)
|
|
rtTabbed, rtTabInfo = fixTabBits(rtTabbed, rtTabInfo, 0b1000)
|
|
ftTabbed=0
|
|
if not hasBk:
|
|
tpTabbed, tpTabInfo = fixTabBits(tpTabbed, tpTabInfo, 0b0010)
|
|
bmTabbed, bmTabInfo = fixTabBits(bmTabbed, bmTabInfo, 0b0010)
|
|
ltTabbed, ltTabInfo = fixTabBits(ltTabbed, ltTabInfo, 0b0010)
|
|
rtTabbed, rtTabInfo = fixTabBits(rtTabbed, rtTabInfo, 0b0010)
|
|
bkTabbed=0
|
|
if not hasLt:
|
|
tpTabbed, tpTabInfo = fixTabBits(tpTabbed, tpTabInfo, 0b0100)
|
|
bmTabbed, bmTabInfo = fixTabBits(bmTabbed, bmTabInfo, 0b0001)
|
|
bkTabbed, bkTabInfo = fixTabBits(bkTabbed, bkTabInfo, 0b0001)
|
|
ftTabbed, ftTabInfo = fixTabBits(ftTabbed, ftTabInfo, 0b0001)
|
|
ltTabbed=0
|
|
if not hasRt:
|
|
tpTabbed, tpTabInfo = fixTabBits(tpTabbed, tpTabInfo, 0b0001)
|
|
bmTabbed, bmTabInfo = fixTabBits(bmTabbed, bmTabInfo, 0b0100)
|
|
bkTabbed, bkTabInfo = fixTabBits(bkTabbed, bkTabInfo, 0b0100)
|
|
ftTabbed, ftTabInfo = fixTabBits(ftTabbed, ftTabInfo, 0b0100)
|
|
rtTabbed=0
|
|
|
|
# Layout positions are specified in a grid of rows and columns
|
|
row0=(1,0,0,0) # top row
|
|
row1y=(2,0,1,0) # second row, offset by Y
|
|
row1z=(2,0,0,1) # second row, offset by Z
|
|
row2=(3,0,1,1) # third row, always offset by Y+Z
|
|
|
|
col0=(1,0,0,0) # left column
|
|
col1x=(2,1,0,0) # second column, offset by X
|
|
col1z=(2,0,0,1) # second column, offset by Z
|
|
col2xx=(3,2,0,0) # third column, offset by 2*X
|
|
col2xz=(3,1,0,1) # third column, offset by X+Z
|
|
col3xzz=(4,1,0,2) # fourth column, offset by X+2*Z
|
|
col3xxz=(4,2,0,1) # fourth column, offset by 2*X+Z
|
|
col4=(5,2,0,2) # fifth column, always offset by 2*X+2*Z
|
|
col5=(6,3,0,2) # sixth column, always offset by 3*X+2*Z
|
|
|
|
# layout format:(rootx),(rooty),Xlength,Ylength,tabInfo,tabbed,pieceType
|
|
# root= (spacing,X,Y,Z) * values in tuple
|
|
# tabInfo= <abcd> 0=holes 1=tabs
|
|
# tabbed= <abcd> 0=no tabs 1=tabs on this side
|
|
# (sides: a=top, b=right, c=bottom, d=left)
|
|
# pieceType: 1=XY, 2=XZ, 3=ZY
|
|
tpFace=1
|
|
bmFace=1
|
|
ftFace=2
|
|
bkFace=2
|
|
ltFace=3
|
|
rtFace=3
|
|
|
|
def reduceOffsets(aa, start, dx, dy, dz):
|
|
for ix in range(start+1,len(aa)):
|
|
(s,x,y,z) = aa[ix]
|
|
aa[ix] = (s-1, x-dx, y-dy, z-dz)
|
|
|
|
# note first two pieces in each set are the X-divider template and Y-divider template respectively
|
|
pieces=[]
|
|
if layout==1: # Diagramatic Layout
|
|
rr = deepcopy([row0, row1z, row2])
|
|
cc = deepcopy([col0, col1z, col2xz, col3xzz])
|
|
if not hasFt: reduceOffsets(rr, 0, 0, 0, 1) # remove row0, shift others up by Z
|
|
if not hasLt: reduceOffsets(cc, 0, 0, 0, 1)
|
|
if not hasRt: reduceOffsets(cc, 2, 0, 0, 1)
|
|
if hasBk: pieces.append([cc[1], rr[2], X,Z, bkTabInfo, bkTabbed, bkFace])
|
|
if hasLt: pieces.append([cc[0], rr[1], Z,Y, ltTabInfo, ltTabbed, ltFace])
|
|
if hasBm: pieces.append([cc[1], rr[1], X,Y, bmTabInfo, bmTabbed, bmFace])
|
|
if hasRt: pieces.append([cc[2], rr[1], Z,Y, rtTabInfo, rtTabbed, rtFace])
|
|
if hasTp: pieces.append([cc[3], rr[1], X,Y, tpTabInfo, tpTabbed, tpFace])
|
|
if hasFt: pieces.append([cc[1], rr[0], X,Z, ftTabInfo, ftTabbed, ftFace])
|
|
elif layout==2: # 3 Piece Layout
|
|
rr = deepcopy([row0, row1y])
|
|
cc = deepcopy([col0, col1z])
|
|
if hasBk: pieces.append([cc[1], rr[1], X,Z, bkTabInfo, bkTabbed, bkFace])
|
|
if hasLt: pieces.append([cc[0], rr[0], Z,Y, ltTabInfo, ltTabbed, ltFace])
|
|
if hasBm: pieces.append([cc[1], rr[0], X,Y, bmTabInfo, bmTabbed, bmFace])
|
|
elif layout==3: # Inline(compact) Layout
|
|
rr = deepcopy([row0])
|
|
cc = deepcopy([col0, col1x, col2xx, col3xxz, col4, col5])
|
|
if not hasTp: reduceOffsets(cc, 0, 1, 0, 0) # remove col0, shift others left by X
|
|
if not hasBm: reduceOffsets(cc, 1, 1, 0, 0)
|
|
if not hasLt: reduceOffsets(cc, 2, 0, 0, 1)
|
|
if not hasRt: reduceOffsets(cc, 3, 0, 0, 1)
|
|
if not hasBk: reduceOffsets(cc, 4, 1, 0, 0)
|
|
if hasBk: pieces.append([cc[4], rr[0], X,Z, bkTabInfo, bkTabbed, bkFace])
|
|
if hasLt: pieces.append([cc[2], rr[0], Z,Y, ltTabInfo, ltTabbed, ltFace])
|
|
if hasTp: pieces.append([cc[0], rr[0], X,Y, tpTabInfo, tpTabbed, tpFace])
|
|
if hasBm: pieces.append([cc[1], rr[0], X,Y, bmTabInfo, bmTabbed, bmFace])
|
|
if hasRt: pieces.append([cc[3], rr[0], Z,Y, rtTabInfo, rtTabbed, rtFace])
|
|
if hasFt: pieces.append([cc[5], rr[0], X,Z, ftTabInfo, ftTabbed, ftFace])
|
|
|
|
for idx, piece in enumerate(pieces): # generate and draw each piece of the box
|
|
(xs,xx,xy,xz)=piece[0]
|
|
(ys,yx,yy,yz)=piece[1]
|
|
x=xs*spacing+xx*X+xy*Y+xz*Z # root x co-ord for piece
|
|
y=ys*spacing+yx*X+yy*Y+yz*Z # root y co-ord for piece
|
|
dx=piece[2]
|
|
dy=piece[3]
|
|
tabs=piece[4]
|
|
a=tabs>>3&1; b=tabs>>2&1; c=tabs>>1&1; d=tabs&1 # extract tab status for each side
|
|
tabbed=piece[5]
|
|
atabs=tabbed>>3&1; btabs=tabbed>>2&1; ctabs=tabbed>>1&1; dtabs=tabbed&1 # extract tabbed flag for each side
|
|
xspacing=(X-thickness)/(divy+1)
|
|
yspacing=(Y-thickness)/(divx+1)
|
|
xholes = 1 if piece[6]<3 else 0
|
|
yholes = 1 if piece[6]!=2 else 0
|
|
wall = 1 if piece[6]>1 else 0
|
|
floor = 1 if piece[6]==1 else 0
|
|
railholes = 1 if piece[6]==3 else 0
|
|
|
|
group = newGroup(self)
|
|
|
|
if schroff and railholes:
|
|
log("rail holes enabled on piece %d at (%d, %d)" % (idx, x+thickness,y+thickness))
|
|
log("abcd = (%d,%d,%d,%d)" % (a,b,c,d))
|
|
log("dxdy = (%d,%d)" % (dx,dy))
|
|
rhxoffset = rail_mount_depth + thickness
|
|
if idx == 1:
|
|
rhx=x+rhxoffset
|
|
elif idx == 3:
|
|
rhx=x-rhxoffset+dx
|
|
else:
|
|
rhx=0
|
|
log("rhxoffset = %d, rhx= %d" % (rhxoffset, rhx))
|
|
rystart=y+(rail_height/2)+thickness
|
|
if rows == 1:
|
|
log("just one row this time, rystart = %d" % rystart)
|
|
rh1y=rystart+rail_mount_centre_offset
|
|
rh2y=rh1y+(row_centre_spacing-rail_mount_centre_offset)
|
|
group.add(getCircle(rail_mount_radius,(rhx,rh1y)))
|
|
group.add(getCircle(rail_mount_radius,(rhx,rh2y)))
|
|
else:
|
|
for n in range(0,rows):
|
|
log("drawing row %d, rystart = %d" % (n+1, rystart))
|
|
# if holes are offset (eg. Vector T-strut rails), they should be offset
|
|
# toward each other, ie. toward the centreline of the Schroff row
|
|
rh1y=rystart+rail_mount_centre_offset
|
|
rh2y=rh1y+row_centre_spacing-rail_mount_centre_offset
|
|
group.add(getCircle(rail_mount_radius,(rhx,rh1y)))
|
|
group.add(getCircle(rail_mount_radius,(rhx,rh2y)))
|
|
rystart+=row_centre_spacing+row_spacing+rail_height
|
|
|
|
# generate and draw the sides of each piece
|
|
side(group,(x,y),(d,a),(-b,a),atabs * (-thickness if a else thickness),dx,(1,0),a,0,(keydivfloor|wall) * (keydivwalls|floor) * divx*yholes*atabs,yspacing) # side a
|
|
side(group,(x+dx,y),(-b,a),(-b,-c),btabs * (thickness if b else -thickness),dy,(0,1),b,0,(keydivfloor|wall) * (keydivwalls|floor) * divy*xholes*btabs,xspacing) # side b
|
|
if atabs:
|
|
side(group,(x+dx,y+dy),(-b,-c),(d,-c),ctabs * (thickness if c else -thickness),dx,(-1,0),c,0,0,0) # side c
|
|
else:
|
|
side(group,(x+dx,y+dy),(-b,-c),(d,-c),ctabs * (thickness if c else -thickness),dx,(-1,0),c,0,(keydivfloor|wall) * (keydivwalls|floor) * divx*yholes*ctabs,yspacing) # side c
|
|
if btabs:
|
|
side(group,(x,y+dy),(d,-c),(d,a),dtabs * (-thickness if d else thickness),dy,(0,-1),d,0,0,0) # side d
|
|
else:
|
|
side(group,(x,y+dy),(d,-c),(d,a),dtabs * (-thickness if d else thickness),dy,(0,-1),d,0,(keydivfloor|wall) * (keydivwalls|floor) * divy*xholes*dtabs,xspacing) # side d
|
|
|
|
if idx==0:
|
|
if not keydivwalls:
|
|
a=b=c=d=1
|
|
atabs=btabs=ctabs=dtabs=0
|
|
y=4*spacing+1*Y+2*Z # root y co-ord for piece
|
|
for n in range(0,divx): # generate X dividers
|
|
group = newGroup(self)
|
|
x=n*(spacing+X) # root x co-ord for piece
|
|
side(group,(x,y),(d,a),(-b,a),keydivfloor*atabs*(-thickness if a else thickness),dx,(1,0),a,1,0,0) # side a
|
|
side(group,(x+dx,y),(-b,a),(-b,-c),keydivwalls*btabs*(thickness if keydivwalls*b else -thickness),dy,(0,1),b,1,divy*xholes,xspacing) # side b
|
|
side(group,(x+dx,y+dy),(-b,-c),(d,-c),keydivfloor*ctabs*(thickness if c else -thickness),dx,(-1,0),c,1,0,0) # side c
|
|
side(group,(x,y+dy),(d,-c),(d,a),keydivwalls*dtabs*(-thickness if d else thickness),dy,(0,-1),d,1,0,0) # side d
|
|
elif idx==1:
|
|
y=5*spacing+1*Y+3*Z # root y co-ord for piece
|
|
for n in range(0,divy): # generate Y dividers
|
|
group = newGroup(self)
|
|
x=n*(spacing+Z) # root x co-ord for piece
|
|
side(group,(x,y),(d,a),(-b,a),keydivwalls*atabs*(-thickness if a else thickness),dx,(1,0),a,1,divx*yholes,yspacing) # side a
|
|
side(group,(x+dx,y),(-b,a),(-b,-c),keydivfloor*btabs*(thickness if b else -thickness),dy,(0,1),b,1,0,0) # side b
|
|
side(group,(x+dx,y+dy),(-b,-c),(d,-c),keydivwalls*ctabs*(thickness if c else -thickness),dx,(-1,0),c,1,0,0) # side c
|
|
side(group,(x,y+dy),(d,-c),(d,a),keydivfloor*dtabs*(-thickness if d else thickness),dy,(0,-1),d,1,0,0) # side d
|
|
|
|
# Create effect instance and apply it.
|
|
BoxMaker().run() |