480 lines
23 KiB
Python
480 lines
23 KiB
Python
#!/usr/bin/python
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import sys
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from Hurricane import *
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from CRL import *
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import helpers
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from helpers.io import ErrorMessage as Error
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from helpers import trace
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import oroshi
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from capacitorunit import CapacitorUnit
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from capacitormatrix import CapacitorStack
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from collections import OrderedDict
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import numpy
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## Route two matched capacitors, C1 and C2, drawn in a capacitor matrix.
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# Connections are put in place with reference to a given matching scheme.
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# Elementary capacitor units are connected to horizontal and vertical routing
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# tracks that represent top plates and bottom plates nets of C1 and C2.
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# Supported types of capacitors are Poly-Poly and Metal-Metal.
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# Technologycal rules are provided by 350 nm AMS CMOS technology with
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# three-four metal layers. Metal layers that are used for routeing are
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# placed similarly to horziontal-vertical (HV) symbolic Alliance CAD tool router,
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# where horizontal metal channels are drawn in metal 2 and the vertical ones are
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# in metal 3. Given a matrix of dimensions \f$ R*C \f$, the total number of
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# vertical tracks is \f$ 2C+2 \f$ equivalent to \f$ C+1 \f$ couples,
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# ensuring that every elementary capacitor is positioned between four
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# vertical tracks, two from each side. In fact, every adjacent couple of these
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# tracks represent top plates and bottom plates of C1 or C2 as shown in Figure 1.
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#
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# \image html Layout.png "Layout" width=.1\linewidth
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#
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# An elementary capacitor unit can be a part of C1 or C2 according to the
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# matching scheme. However, to respect common-centroid layout specifications,
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# for C1 and C2 to be equal, the matrix number of colums and number of rows
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# must be both even. Addionnally, the number of elementary capacitors dedicated
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# to C1 must be equal to those dedicated to C2. These two conditions are tested
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# in one of the class methods. An exception is raised if at least one of the two
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# is not respected.
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class VerticalRoutingTracks ( CapacitorUnit, CapacitorStack ):
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rules = oroshi.getRules()
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def __init__( self, capacitorInstance, capacitor, minimizeVRT = False ) :
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self.device = capacitorInstance.device
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self.capacitorInstance = capacitorInstance
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self.capacitor = capacitor
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self.matchingScheme = capacitorInstance.matchingScheme
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self.capacitorType = capacitorInstance.capacitorType
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self.abutmentBox = capacitorInstance.abutmentBox
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self.matrixDim = self.capacitorInstance.matrixDim
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self.nets = capacitorInstance.nets
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self.capacitorsNumber = capacitorInstance.capacitorsNumber
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self.dummyRing = capacitorInstance.dummyRing
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self.dummyElement = capacitorInstance.dummyElement
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self.capacitorIds = range(0,self.capacitorsNumber)
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self.abutmentBox_spacing = capacitorInstance.abutmentBox_spacing
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self.vRoutingTrack_width = self.capacitorInstance.vRoutingTrack_width
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self.vRoutingTrackXCenter = []
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self.vRoutingTrackDict = {}
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self.minimizeVRT = minimizeVRT
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self.vRTsToEliminate = []
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self.vRTsDistribution = []
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self.platesDistribution = []
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return
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def getVTrackYMin ( self ): return self.vRoutingTrackDict["YMin"] - self.hRoutingTrack_width/2
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def getVTrackYMax ( self ): return self.vRoutingTrackDict["YMax"] + self.hRoutingTrack_width/2
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## Sets vertical stretching value considering spacing between elementary capacitors in the matrix.
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# \return stratching value.
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def __setStretching__( self ): return self.minSpacing_botPlate + self.abutmentBox_spacing/2
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## Defines technology rules used to draw the layout. Some of the rules, namely those describing routeing layers and tracks are applicable for both MIM and PIP capacitors. However, cuts rules are different. \remark All \c CapacitorStack class rules are also reloaded in this class. An exception is raised if the entered capacitor type is unsupported.
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# \return a dictionary with rules labels as keys and rules content as values.
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def setRules ( self ):
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CapacitorStack.setRules( self )
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self.minWidth_hRoutingTrackCut = VerticalRoutingTracks.rules.minWidth_cut2
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self.minWidth_hRoutingLayer_vRoutingTrack_cut = VerticalRoutingTracks.rules.minWidth_cut2
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self.minWidth_hRoutingTrack = VerticalRoutingTracks.rules.minWidth_metal2
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self.minEnclosure_hRoutingLayer_vRoutingTrack_cut = VerticalRoutingTracks.rules.minEnclosure_metal2_cut2
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self.minEnclosure_hRoutingTrackCut = VerticalRoutingTracks.rules.minEnclosure_metal2_cut2
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self.minWidth_hRoutingLayer = VerticalRoutingTracks.rules.minWidth_metal2
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self.minSpacing_hRoutingTrack = VerticalRoutingTracks.rules.minSpacing_metbot
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return
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def create( self ):
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UpdateSession.open ()
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self.setRules ()
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vRoutingTracksLayer = DataBase.getDB().getTechnology().getLayer("metal3" )
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#print 'self.capacitorInstance.doMatrix:', self.capacitorInstance.doMatrix
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#print 'self.capacitorsNumber:', self.capacitorsNumber
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if self.capacitorInstance.doMatrix == True and self.capacitorsNumber > 1 :
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self.minimizeVRTs()
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self.computeVRTDimensions()
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self.drawVRoutingTracks( vRoutingTracksLayer )
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else : raise Error(1, 'create() : Impossible to route. This class only routes a matrix of two or more capacitors. Please use <routeCapacitorMatrix> class instead.')
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UpdateSession.close ()
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return
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## Iteratively draws vertical routing tracks given the physical layer
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# \c vRoutingTracksLayer. Every elementary capacitor is consequently
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# positioned between four routing tracks, two from each side.
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# Each couple of adjacent routeing tracks represent top plate and
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# bottom plate nets of Ci, where i is in [1,2]. As given in Figure 2,
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# capacitor \f$ C_{ij} \f$ with an even j value situated in even columns
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# have and inversely for odd columns numbers.
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def drawVRoutingTracks ( self, vRoutingTracksLayer ) :
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netsDistribution = self.__setNetsDistribution__()
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k = 0
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for j in range( 0, self.matrixDim["columns"] + 1 ):
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for key in self.vRoutingTrackXCenter[j]:
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if self.vRoutingTrackXCenter[j][key] is not None:
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Vertical.create( netsDistribution[j][k]
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, vRoutingTracksLayer
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, self.vRoutingTrackXCenter[j][key]
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, self.vRoutingTrack_width
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, self.getVTrackYMin()
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, self.getVTrackYMax() )
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k = k + 1 if k < len(key)-1 else 0
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return
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def computeVRTDimensions ( self ) :
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self.hRoutingTrack_width = max( self.minWidth_hRoutingTrack, self.minWidth_hRoutingTrackCut + 2*self.minEnclosure_hRoutingTrackCut )
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abutmentBoxYMin = self.capacitorInstance.computeAbutmentBoxDimensions( self.abutmentBox_spacing )["YMin"]
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abutmentBoxYMax = abutmentBoxYMin + self.capacitorInstance.computeAbutmentBoxDimensions( self.abutmentBox_spacing )["height"]
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self.minimumPosition = abutmentBoxYMin - self.__setStretching__() - self.hpitch + self.metal2Width
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self.maximumPosition = abutmentBoxYMax + self.__setStretching__() + self.hpitch - self.metal2Width
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height = self.maximumPosition - self.minimumPosition
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heightAdjust = height % (2*self.hpitch)
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if heightAdjust:
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heightAdjust = 2*self.hpitch - heightAdjust
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trace( 101, '\tAdjust height: {0}\n'.format( DbU.getValueString(heightAdjust) ))
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trace( 101, '\tHeight before adjust: {0}\n'.format( DbU.getValueString(self.maximumPosition - self.minimumPosition) ))
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trace( 101, '\tminimum before adjust: {0}\n'.format( DbU.getValueString(self.minimumPosition) ))
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self.maximumPosition += heightAdjust/2
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self.minimumPosition -= heightAdjust/2
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trace( 101, '\tHeight after adjust: {0}\n'.format( DbU.getValueString(self.maximumPosition - self.minimumPosition) ))
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trace( 101, '\tminimum after adjust: {0}\n'.format( DbU.getValueString(self.minimumPosition) ))
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vRTsNumber = self.__computeVRTsNumber__()
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#self.vRoutingTrackDict["YMin"] = self.minimumPosition - vRTsNumber*(self.hRoutingTrack_width + self.minSpacing_hRoutingTrack)
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#self.vRoutingTrackDict["YMax"] = self.maximumPosition + vRTsNumber*(self.hRoutingTrack_width + self.minSpacing_hRoutingTrack)
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self.vRoutingTrackDict["YMin"] = self.minimumPosition - (vRTsNumber-1)*self.hpitch
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self.vRoutingTrackDict["YMax"] = self.maximumPosition + (vRTsNumber-1)*self.hpitch
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self.__setPlatesDistribution__()
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self.computeXCenters()
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return
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def __computeVRTsNumber__ ( self ):
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if self.dummyElement == True :
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vRTsNumber = 2*self.capacitorsNumber - 1
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else :
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vRTsNumber = 2*self.capacitorsNumber + 1 if self.dummyRing == True else 2*self.capacitorsNumber
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return vRTsNumber
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def computeXCenters( self ):
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unitCapDim = self.capacitorInstance.getCapDim()
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abutmentBoxUnitCap_width = CapacitorUnit.computeAbutmentBoxDimensions( self, unitCapDim )["width"]
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unitCapXMin = self.abutmentBox.getXMin() if self.dummyRing == False else self.abutmentBox.getXMin() + abutmentBoxUnitCap_width + self.capacitorInstance.abutmentBox_spacing
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vRoutingTrack_spacing = self.capacitorInstance.minSpacing_vRoutingTrack
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[ factor1 , factor2 ] = [ self.capacitorsNumber , self.capacitorsNumber-1 ] if ( self.capacitorsNumber % 2 == 0 ) else [ self.capacitorsNumber + 1 , self.capacitorsNumber ]
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if self.vRTsToEliminate[0][0] == 1 :
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self.vRoutingTrackXCenter.append( OrderedDict() )
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self.vRoutingTrackXCenter[0][ self.platesDistribution[0][0] ] = unitCapXMin - factor1*vRoutingTrack_spacing - (factor2)*self.vRoutingTrack_width - self.vRoutingTrack_width/2
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else :
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self.vRoutingTrackXCenter.append( OrderedDict() )
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self.vRoutingTrackXCenter[0][ self.platesDistribution[0][0] ] = None
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leftVRTNumber = self.capacitorsNumber if ( self.capacitorsNumber % 2 == 0 ) else self.capacitorsNumber + 1
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for k in range( 1, leftVRTNumber ):
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self.vRoutingTrackXCenter[0][self.platesDistribution[0][k]] = unitCapXMin - (factor1-k)*vRoutingTrack_spacing -(factor2-k)*self.vRoutingTrack_width - self.vRoutingTrack_width/2 if self.vRTsToEliminate[0][k] == 1 else None
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#print('self.vRoutingTrackXCenter',self.vRoutingTrackXCenter)
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for j in range( 1, self.matrixDim["columns"] + 1 ):
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factor3 = j - 1 if self.dummyRing == False else j
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unitCapXMin = self.abutmentBox.getXMin() + factor3*( abutmentBoxUnitCap_width + self.capacitorInstance.abutmentBox_spacing )
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unitCapXMax = unitCapXMin + abutmentBoxUnitCap_width
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if self.vRTsToEliminate[j][0] == 1:
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self.vRoutingTrackXCenter.append( OrderedDict() )
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self.vRoutingTrackXCenter[j][ self.platesDistribution[j][0] ] = unitCapXMax + vRoutingTrack_spacing + self.vRoutingTrack_width/2
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else :
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self.vRoutingTrackXCenter.append( OrderedDict() )
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self.vRoutingTrackXCenter[j][ self.platesDistribution[j][0] ] = None
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if self.capacitorsNumber % 2 == 0:
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rightVRTNumber = self.capacitorsNumber
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else :
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if (j % 2 == 0) :
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rightVRTNumber = self.capacitorsNumber + 1
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else : rightVRTNumber = self.capacitorsNumber - 1 if self.dummyElement == False else self.capacitorsNumber - 2
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for k in range( 1, rightVRTNumber ):
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self.vRoutingTrackXCenter[j][ self.platesDistribution[j][k] ] = unitCapXMax + (k+1)*vRoutingTrack_spacing + (k)*self.vRoutingTrack_width + self.vRoutingTrack_width/2 if self.vRTsToEliminate[j][k] == 1 else None
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#print('self.vRoutingTrackXCenter',self.vRoutingTrackXCenter)
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return
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def __findUsedCapIdsPerColumn__( self ):
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usedCapIdsPerColumn = []
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for j in range(0, self.matrixDim["columns"] ):
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usedCapIdsPerColumn.append( [self.matchingScheme[0][j]] )
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for i in range(1, self.matrixDim["rows"] ):
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usedCapIdsPerColumn[j].append( self.matchingScheme[i][j] )
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usedCapIdsPerColumn[j] = numpy.unique(usedCapIdsPerColumn[j])
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return usedCapIdsPerColumn
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def __findCapIdsToEliminatePerColumn__( self, usedCapIdsPerColumn ):
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capIdsToEliminatePerColumn = []
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for j in range(0, len(usedCapIdsPerColumn) ):
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if len(usedCapIdsPerColumn[j]) == self.capacitorsNumber:
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capIdsToEliminatePerColumn.append( [None] )
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else :
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capIdsToEliminatePerColumn.append( list (set(usedCapIdsPerColumn[j])^set(self.capacitorIds) ) )
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return capIdsToEliminatePerColumn
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def __findCapIdsToEliminate__( self, capIdsToEliminatePerColumn ):
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capIdsToEliminate = []
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capIdsj = capIdsToEliminatePerColumn[0]
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#print('capIdsj',capIdsj)
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sharedVRTIds = self.capacitorIds[0:self.capacitorsNumber/2] if self.capacitorsNumber % 2 == 0 else self.capacitorIds[0: int(self.capacitorsNumber/2+1)]
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#print('sharedVRTIds',sharedVRTIds)
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intersection2 = list( set(capIdsj).intersection(set(sharedVRTIds)) )
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capIdsToEliminate.append( [None] ) if intersection2 == [] else capIdsToEliminate.append( intersection2 )
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for j in range(0, len(capIdsToEliminatePerColumn) ):
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capIdsj = capIdsToEliminatePerColumn[j]
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if (j % 2 == 0):
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sharedVRTIds = self.capacitorIds[self.capacitorsNumber/2 : self.capacitorsNumber] if (self.capacitorsNumber % 2 == 0) else self.capacitorIds[int(self.capacitorsNumber/2+1) : self.capacitorsNumber]
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else:
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sharedVRTIds = self.capacitorIds[0:self.capacitorsNumber/2] if (self.capacitorsNumber % 2 == 0) else self.capacitorIds[0: int(self.capacitorsNumber/2+1)]
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#print('sharedVRTIds',sharedVRTIds)
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if j == len(capIdsToEliminatePerColumn)-1:
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intersection1 = list( set(capIdsj) )
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else :
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capIdsjp1 = capIdsToEliminatePerColumn[j+1]
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intersection1 = list( set(capIdsj).intersection(set(capIdsjp1)) )
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intersection2 = list( set(intersection1).intersection(set(sharedVRTIds)) )
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capIdsToEliminate.append( [None] ) if intersection2 == [] else capIdsToEliminate.append( intersection2 )
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return capIdsToEliminate
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def __findVRTsToEliminate__( self, capIdsToEliminate ):
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#print('capIdsToEliminate',capIdsToEliminate)
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for j in range( 0,len(self.vRTsDistribution) ) :
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for k in range( 0,len(self.vRTsDistribution[j]) ) :
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if k == 0 :
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if self.vRTsDistribution[j][0] in capIdsToEliminate[j] :
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self.vRTsToEliminate.append( [0] )
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self.vRTsToEliminate[j].append( 0 )
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else :
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self.vRTsToEliminate.append( [1] )
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self.vRTsToEliminate[j].append( 1 )
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#print('vRTsToEliminate',self.vRTsToEliminate)
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else :
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if self.vRTsDistribution[j][k] in capIdsToEliminate[j]:
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[self.vRTsToEliminate[j].append( 0 ) for u in range(0,2)]
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else :
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[self.vRTsToEliminate[j].append( 1 ) for u in range(0,2)]
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return
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def minimizeVRTs( self ) :
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self.__setVRTsDistribution__()
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if self.minimizeVRT == False :
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for j in range( 0, self.matrixDim["columns"]+1 ) :
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self.vRTsToEliminate.append( [1] )
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self.vRTsToEliminate[j].append( 1 )
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for k in range( 0,len(self.vRTsDistribution[j]) ) :
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[self.vRTsToEliminate[j].append( 1 ) for u in range(0,2)]
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elif self.minimizeVRT == True :
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usedCapIdsPerColumn = self.__findUsedCapIdsPerColumn__ ()
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capIdsToEliminatePerColumn = self.__findCapIdsToEliminatePerColumn__(usedCapIdsPerColumn )
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capIdsToEliminate = self.__findCapIdsToEliminate__ (capIdsToEliminatePerColumn)
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self.__findVRTsToEliminate__ (capIdsToEliminate )
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#print("self.matchingScheme" ,self.matchingScheme)
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#print("usedCapIdsPerColumn" ,usedCapIdsPerColumn)
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#print("capIdsToEliminatePerColumn",capIdsToEliminatePerColumn)
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#print("capIdsToEliminate" ,capIdsToEliminate)
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#print('self.vRTsToEliminate' ,self.vRTsToEliminate)
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else : raise Error(1,'minimizeVRTs() : ')
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return
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def __setVRTsDistribution__( self ):
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element = [ self.capacitorIds[0:self.capacitorsNumber/2], self.capacitorIds[self.capacitorsNumber/2:self.capacitorsNumber] ] if self.capacitorsNumber % 2 == 0 else [ self.capacitorIds[0:int( self.capacitorsNumber/2 + 1 )], self.capacitorIds[int( self.capacitorsNumber/2 + 1 ):self.capacitorsNumber] ]
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u = 0
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for j in range(0,self.matrixDim["columns"]+1) :
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self.vRTsDistribution.append( element[u] )
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u = u+1 if u < 1 else 0
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#print('self.vRTsDistribution',self.vRTsDistribution)
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return
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def __setNetsDistribution__( self ):
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netsList = self.nets[0:len(self.nets)-1] if self.dummyRing == True and self.dummyElement == False else self.nets
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element = [ netsList[0:len(netsList)/2], netsList[len(netsList)/2:len(netsList)] ] if len(netsList) % 2 == 0 else [ netsList[0:int( len(netsList)/2 + 1 )], netsList[int( len(netsList)/2 + 1 ):len(netsList)] ]
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u = 0
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netsDistribution = []
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for j in range(0,self.matrixDim["columns"]+1) :
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netsDistribution.append( [element[u][0][0]] )
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netsDistribution[j].append( element[u][0][1] )
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for k in range(1,len(element[u])):
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netsDistribution[j].append( element[u][k][0] )
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netsDistribution[j].append( element[u][k][1] )
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u = u+1 if u < 1 else 0
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#print('netsDistribution',netsDistribution)
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return netsDistribution
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def __setPlatesDistribution__( self ):
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element = [ self.capacitorIds[0:self.capacitorsNumber/2], self.capacitorIds[self.capacitorsNumber/2:self.capacitorsNumber] ] if self.capacitorsNumber % 2 == 0 else [ self.capacitorIds[0:int( self.capacitorsNumber/2 + 1 )], self.capacitorIds[int( self.capacitorsNumber/2 + 1 ):self.capacitorsNumber] ]
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u = 0
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for j in range(0,self.matrixDim["columns"]+1) :
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self.platesDistribution.append( ['t' + str(element[u][0])] )
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#print('self.platesDistribution',self.platesDistribution)
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if self.dummyElement == False or self.dummyElement == True and j % 2 == 0 and len(element[u]) > 1 :
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self.platesDistribution[j].append( 'b' + str(element[u][0]) )
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for k in element[u][1:len(element[u])]:
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self.platesDistribution[j].append( 't' + str(k) )
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if self.dummyElement == False or self.dummyElement == True and j % 2 == 0 or self.dummyElement == True and j % 2 != 0 and k != element[u][len(element[u])-1] :
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self.platesDistribution[j].append( 'b' + str(k) )
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u = u+1 if u < 1 else 0
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#print('self.platesDistribution',self.platesDistribution)
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return
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def gethRoutingTrack_width ( self ) : return self.hRoutingTrack_width
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def getvRoutingTrackXCenter ( self ) : return self.vRoutingTrackXCenter
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def scriptMain( **kw ):
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editor = None
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if kw.has_key('editor') and kw['editor']:
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editor = kw['editor']
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UpdateSession.open()
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Device = AllianceFramework.get().createCell( 'capacitor' )
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Device.setTerminal( True )
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bottomPlate_net0 = Net.create( Device, 'b0' )
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bottomPlate_net1 = Net.create( Device, 'b1' )
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bottomPlate_net2 = Net.create( Device, 'b2' )
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bottomPlate_net3 = Net.create( Device, 'b3' )
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bottomPlate_net0.setExternal( True )
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bottomPlate_net1.setExternal( True )
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bottomPlate_net2.setExternal( True )
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bottomPlate_net3.setExternal( True )
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b0 = Device.getNet("b0")
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b1 = Device.getNet("b1")
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b2 = Device.getNet("b2")
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b3 = Device.getNet("b3")
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topPlate_net0 = Net.create( Device, 't0' )
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topPlate_net1 = Net.create( Device, 't1' )
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topPlate_net2 = Net.create( Device, 't2' )
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topPlate_net3 = Net.create( Device, 't3' )
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topPlate_net0.setExternal( True )
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topPlate_net1.setExternal( True )
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topPlate_net2.setExternal( True )
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topPlate_net3.setExternal( True )
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t0 = Device.getNet("t0")
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t1 = Device.getNet("t1")
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t2 = Device.getNet("t2")
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t3 = Device.getNet("t3")
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if editor:
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UpdateSession.close()
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editor.setCell( Device )
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editor.fit()
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UpdateSession.open()
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nets = [[t0, b0] , [t1, b1] , [t2, b2] ] # [t3, b3] ]
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#capacitorInstance = CapacitorStack( Device, capacitance, 'MIMCap', [0,0], nets, unitCap = 93, matchingMode = True, matchingScheme = [ ['C2','C2','C2','C2'] , ['C1','C2','C2','C2'] , ['C1','C2','C2','C2'] , ['C1','C2','C2','C1'] ] )
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capacitorInstance = CapacitorStack( Device, [372,1116], 'MIMCap', [0,0], nets,unitCap = 93, matrixDim = [4,4], matchingMode = True, matchingScheme = [ [1,1,1,0] , [0,1,1,1] , [1,1,1,0] , [0,1,1,1]], dummyRing = True)
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# capacitorInstance = CapacitorStack( Device, [372,1116], 'MIMCap', [0,0], nets,unitCap = 93, matrixDim = [4,4], matchingMode = True, matchingScheme = [ [1,1,1,0] , [0,1,1,1] , [1,1,1,0] , [0,1,1,1] ], dummyRing = True)
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# capacitorInstance = CapacitorStack( Device, [279], 'MIMCap', [0,0], nets, unitCap = 279 ) #, matrixDim = [4,4], matchingMode = True, matchingScheme = [ [1,1,1,0] , [0,1,2,1] , [1,1,1,0] , [2,1,1,1] ], dummyElement = True )#dummyRing = True)
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# capacitorInstance = CapacitorStack( Device, [279,1023, 186], 'MIMCap', [0,0], nets, unitCap = 93, matrixDim = [4,4], matchingMode = True, matchingScheme = [ [1,1,1,0] , [0,1,2,1] , [1,1,1,0] , [2,1,1,1] ], dummyElement = True )#dummyRing = True)
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# capacitorInstance = CapacitorStack( Device, capacitance, 'MIMCap', [0,0], nets, unitCap = 93, matchingMode = True, matchingScheme = [ ['C2','C2','C1','C2'] , ['C1','C2','C2','C1'] , ['C1','C1','C2','C3'] , ['C1','C1','C2','C3'] ] )
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# capacitorInstance = CapacitorStack( Device, capacitance, 'MIMCap', [0,0], nets, unitCap = 93, matchingMode = True, matchingScheme = [ ['C1','C4','C1','C2'] , ['C1','C2','C4','C1'] , ['C3','C1','C4','C3'] , ['C3','C1','C2','C3'] ] )
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capacitor = capacitorInstance.create( )
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capWithVRT = VerticalRoutingTracks( capacitorInstance, capacitor, True ) # )
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capWithVRT.create()
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AllianceFramework.get().saveCell( Device, Catalog.State.Views )
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return True
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