#!/usr/bin/python import sys from coriolis.Hurricane import DataBase, Net, \ DbU, Point, Box, Pad, Rectilinear from coriolis import Cfg from coriolis.CRL import AllianceFramework, Catalog, Gds from coriolis.helpers import l, u from coriolis.helpers.overlay import CfgCache, UpdateSession def testRectilinear ( editor ): """Check Hurricane.Rectilinear class.""" with CfgCache(priority=Cfg.Parameter.Priority.UserFile) as cfg: cfg.misc.minTraceLevel = 17000 cfg.misc.maxTraceLevel = 18000 with UpdateSession(): cell = AllianceFramework.get().createCell( 'Rectilinear' ) cell.setTerminalNetlist( True ) cell.setAbutmentBox( Box( l(-5.0), l(-5.0), l(400.0), l(200.0) ) ) #cell.setAbutmentBox( Box( l(-5.0), l(-5.0), l(21.0), l(35.0) ) ) if editor: editor.setCell( cell ) editor.fit() technology = DataBase.getDB().getTechnology() metal1 = technology.getLayer( "METAL1" ) metal2 = technology.getLayer( "METAL2" ) metal3 = technology.getLayer( "METAL3" ) metal4 = technology.getLayer( "METAL4" ) poly = technology.getLayer( "POLY" ) ptrans = technology.getLayer( "PTRANS" ) ntrans = technology.getLayer( "NTRANS" ) pdif = technology.getLayer( "PDIF" ) ndif = technology.getLayer( "NDIF" ) contdifn = technology.getLayer( "CONT_DIF_N" ) contdifp = technology.getLayer( "CONT_DIF_P" ) nwell = technology.getLayer( "NWELL" ) contpoly = technology.getLayer( "CONT_POLY" ) ntie = technology.getLayer( "NTIE" ) with UpdateSession(): net = Net.create( cell, 'my_net' ) net.setExternal( True ) points = [ Point( l( 0.0), l( 0.0) ) , Point( l( 0.0), l( 10.0) ) , Point( l( 20.0), l( 30.0) ) , Point( l( 30.0), l( 30.0) ) , Point( l( 30.0), l( 20.0) ) , Point( l( 10.0), l( 0.0) ) , Point( l( 0.0), l( 0.0) ) ] r = Rectilinear.create( net, metal2, points ) #print( 'Normalized and manhattanized contour:' ) #i = 0 #for point in p.getMContour(): # print( '| %d '%i, point, '[%fum %fum]' % ( u(point.getX()), u(point.getY()) )) # i += 1 #points = [ Point( l( 0.0), l( 40.0) ) # 0 # , Point( l( 30.0), l( 40.0) ) # 1 # , Point( l( 30.0), l( 60.0) ) # 2 # , Point( l( 50.0), l( 60.0) ) # 3 # , Point( l( 50.0), l( 80.0) ) # 4 # , Point( l( 90.0), l( 80.0) ) # 5 # , Point( l( 90.0), l( 50.0) ) # 6 # , Point( l( 60.0), l( 50.0) ) # 7 # , Point( l( 60.0), l( 30.0) ) # 8 # , Point( l( 70.0), l( 30.0) ) # 9 # , Point( l( 70.0), l( 20.0) ) # 10 # , Point( l( 90.0), l( 20.0) ) # 11 # , Point( l( 90.0), l( 0.0) ) # 12 # , Point( l( 20.0), l( 0.0) ) # 13 # , Point( l( 20.0), l( 20.0) ) # 14 # , Point( l( 0.0), l( 20.0) ) # 15 # , Point( l( 0.0), l( 40.0) ) ] # 16 # Super-test rectilinear. points = [ Point( l( 0.0), l( 0.0) ) # 0 , Point( l( 0.0), l( 20.0) ) # 1 , Point( l( 10.0), l( 20.0) ) # 2 , Point( l( 10.0), l( 30.0) ) # 3 , Point( l( 20.0), l( 30.0) ) # 4 , Point( l( 20.0), l( 40.0) ) # 5 , Point( l( 40.0), l( 40.0) ) # 6 , Point( l( 40.0), l( 80.0) ) # 7 , Point( l( 20.0), l( 80.0) ) # 8 , Point( l( 20.0), l( 70.0) ) # 9 , Point( l( 10.0), l( 70.0) ) # 10 , Point( l( 10.0), l( 60.0) ) # 11 , Point( l( 0.0), l( 60.0) ) # 12 , Point( l( 0.0), l(120.0) ) # 13 , Point( l( 10.0), l(120.0) ) # 14 , Point( l( 10.0), l(110.0) ) # 15 , Point( l( 20.0), l(110.0) ) # 16 , Point( l( 20.0), l(100.0) ) # 17 , Point( l( 40.0), l(100.0) ) # 18 , Point( l( 40.0), l(140.0) ) # 19 , Point( l( 20.0), l(140.0) ) # 20 , Point( l( 20.0), l(150.0) ) # 21 , Point( l( 10.0), l(150.0) ) # 22 , Point( l( 10.0), l(160.0) ) # 23 , Point( l( 0.0), l(160.0) ) # 24 , Point( l( 0.0), l(180.0) ) # 25 , Point( l( 40.0), l(180.0) ) # 26 , Point( l( 40.0), l(170.0) ) # 27 , Point( l( 50.0), l(170.0) ) # 28 , Point( l( 50.0), l(160.0) ) # 29 , Point( l(150.0), l(160.0) ) # 30 , Point( l(150.0), l(150.0) ) # 31 , Point( l(130.0), l(150.0) ) # 32 , Point( l(130.0), l(140.0) ) # 33 , Point( l(120.0), l(140.0) ) # 34 , Point( l(120.0), l(130.0) ) # 35 , Point( l(110.0), l(130.0) ) # 36 , Point( l(110.0), l(110.0) ) # 37 , Point( l(120.0), l(110.0) ) # 38 , Point( l(120.0), l(100.0) ) # 39 , Point( l(130.0), l(100.0) ) # 40 , Point( l(130.0), l( 90.0) ) # 41 , Point( l(150.0), l( 90.0) ) # 42 , Point( l(150.0), l( 80.0) ) # 43 , Point( l(120.0), l( 80.0) ) # 44 , Point( l(120.0), l( 70.0) ) # 45 , Point( l(110.0), l( 70.0) ) # 46 , Point( l(110.0), l( 50.0) ) # 47 , Point( l(120.0), l( 50.0) ) # 48 , Point( l(120.0), l( 40.0) ) # 49 , Point( l(130.0), l( 40.0) ) # 50 , Point( l(130.0), l( 30.0) ) # 51 , Point( l(150.0), l( 30.0) ) # 52 , Point( l(150.0), l( 20.0) ) # 53 , Point( l( 50.0), l( 20.0) ) # 54 , Point( l( 50.0), l( 10.0) ) # 55 , Point( l( 40.0), l( 10.0) ) # 56 , Point( l( 40.0), l( 0.0) ) # 57 , Point( l( 0.0), l( 0.0) ) ] # 57 #points = [ Point( l( 0.0), l( 0.0) ) # 0 # , Point( l( 0.0), l( 80.0) ) # 1 # , Point( l( 40.0), l( 80.0) ) # 2 # , Point( l( 40.0), l( 60.0) ) # 3 # , Point( l( 20.0), l( 60.0) ) # 4 # , Point( l( 20.0), l( 0.0) ) # 5 # , Point( l( 0.0), l( 0.0) ) ] # 6 r = Rectilinear.create( net, metal2, points ) boxes = [] r.getAsRectangles( boxes ) #print( 'boxes={}'.format( boxes )) for box in boxes: box.translate( l(180.0), l(0.0) ) Pad.create( net, metal3, box ) Gds.save( cell ) def scriptMain ( **kw ): """The mandatory function to be called by Coriolis CGT/Unicorn.""" editor = None if 'editor' in kw and kw['editor']: editor = kw['editor'] testRectilinear( editor ) return True