/* -*- tab-width: 4 -*-
*
* Electric(tm) VLSI Design System
*
* File: Inv_star_wideOutput.java
*
* Copyright (c) 2003, Oracle and/or its affiliates. All rights reserved.
*
* Electric(tm) is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 3 of the License, or
* (at your option) any later version.
*
* Electric(tm) is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with Electric(tm); see the file COPYING. If not, write to
* the Free Software Foundation, Inc., 59 Temple Place, Suite 330,
* Boston, Mass 02111-1307, USA.
*/
package com.sun.electric.tool.generator.layout.gates;
import com.sun.electric.database.hierarchy.Cell;
import com.sun.electric.database.prototype.PortCharacteristic;
import com.sun.electric.database.topology.PortInst;
import com.sun.electric.tool.generator.layout.FoldedMos;
import com.sun.electric.tool.generator.layout.FoldedNmos;
import com.sun.electric.tool.generator.layout.FoldedPmos;
import com.sun.electric.tool.generator.layout.FoldsAndWidth;
import com.sun.electric.tool.generator.layout.LayoutLib;
import com.sun.electric.tool.generator.layout.StdCellParams;
import com.sun.electric.tool.generator.layout.TechType;
import com.sun.electric.tool.generator.layout.TrackRouter;
import com.sun.electric.tool.generator.layout.TrackRouterH;
import com.sun.electric.tool.Job;
/**
* Create inverters with wide output busses.
*/
/** run a wide output bus in metal-1 along n-well/p-well boundary */
/** Tricky: Normally the strong PMOS is folded and the right most
* source/drain is ground. However, if the strong PMOS is so small
* that it has only one fold then the right most source/drain is the
* output. This creates a special case for the weak PMOS because the
* weak PMOS overlaps the strong PMOS's right most source/drain. When
* the strong PMOS gets very small, we have to mirror the weak PMOS
* about it's gate. */
public class Inv2iKp {
// private static final double outHiY = 11.0;
private static final double outLoY = -11.0;
private static final double outBusWidth = 10;
private static final double outBusSpace = 3;
private static final double outY = 0;
private static final double weakRatio = 10;
private static class MyGateSpace implements FoldedMos.GateSpace {
double dogBoneExtra;
MyGateSpace(TechType tech) {
dogBoneExtra = tech.getGateToDiffContSpaceDogBone() -
tech.getGateToDiffContSpace();
}
public double getExtraSpace(double requiredExtraSpace, int foldNdx,
int nbFolds, int spaceNdx, int nbGates){
return (foldNdx==nbFolds-1 && spaceNdx==1) ?
dogBoneExtra
:
requiredExtraSpace;
}
}
private static void error(boolean pred, String msg) {
Job.error(pred, msg);
}
// If strong PMOS has only one fold then connect ODD src/drn of weak
// NMOS to ground
private static final StdCellParams.SelectSrcDrn flipWeakMos =
new StdCellParams.SelectSrcDrn() {
public boolean connectThisOne(int mosNdx, int srcDrnNdx) {
if (mosNdx==0) {
return srcDrnNdx%2==1;
} else if (mosNdx==1) {
return srcDrnNdx%2==0;
} else {
error(true, "more than two FoldedMos?");
return false;
}
}
};
public static Cell makePart(double sz, StdCellParams stdCell) {
TechType tech = stdCell.getTechType();
sz = stdCell.roundSize(sz);
String nm = "inv2iKp";
sz = stdCell.checkMinStrength(sz, 1, nm);
double outsideSpace = 2 + 5 + 1.5; // p1_nd_sp + p1m1_wid + p1_p1_sp/2
double insideSpace = outBusWidth/2 + outBusSpace - .5; // MOS diff surrounds m1 by .5
double spaceAvail = stdCell.getCellTop() - outsideSpace - insideSpace;
// find number of folds and width of PMOS
double totWidP = sz * 6;
FoldsAndWidth fwP = stdCell.calcFoldsAndWidth(spaceAvail, totWidP, 1);
error(fwP==null, "can't make " + nm + " this small: " + sz);
// find number of folds and width of NMOS
spaceAvail = -insideSpace - (stdCell.getCellBot() + outsideSpace);
double totWidN = sz * 3;
FoldsAndWidth fwN = stdCell.calcFoldsAndWidth(spaceAvail, totWidN, 1);
error(fwN==null, "can't make " + nm + " this small: " + sz);
// Weak NMOS is 1/weakRatio the width of the strong NMOS
double totWidW = Math.max(3, totWidN/weakRatio);
FoldsAndWidth fwW = stdCell.calcFoldsAndWidth(spaceAvail, totWidW, 1);
error(fwW==null, "can't make "+nm+" this small: "+sz);
// create Inverter Part
Cell inv = stdCell.findPart(nm, sz);
if (inv!=null) return inv;
inv = stdCell.newPart(nm, sz);
// leave vertical m1 tracks for in[p], in[n], cross-over
double inNX = 1.5 + 2; // m1_m1_sp/2 + m1_wid/2
double inPX = inNX + 1.5 + 2; // m1_m1_sp/2 + m1_wid/2
double pmosX = inPX + 2 + 3 + 2; // m1_wid/2 + m1_m1_sp + m1_wid/2
double weakX = pmosX + 2 + 3 + 2; // m1_wid/2 + m1_m1_sp + m1_wid/2
double pmosY = insideSpace + fwP.physWid/2;
FoldedMos pmos = new FoldedPmos(pmosX, pmosY, fwP.nbFolds, 1,
fwP.gateWid, inv, tech);
// Insert extra space between the leftmost diffusion contact and the
// leftmost gate.
FoldedMos.GateSpace spaceLastGate = new MyGateSpace(tech);
double weakY = -insideSpace - fwW.physWid/2;
FoldedMos nmosW = new FoldedNmos(weakX, weakY, fwW.nbFolds, 1,
fwW.gateWid, spaceLastGate, 'T', inv, tech);
// strong NMOS overlaps weak NMOS
double nmosX = nmosW.getSrcDrn(fwW.nbFolds).getBounds().getCenterX();
double nmosY = -insideSpace - fwN.physWid / 2;
FoldedMos nmos = new FoldedNmos(nmosX, nmosY, fwN.nbFolds, 1,
fwN.gateWid, inv, tech);
// inverter output: m1_wid/2 + m1_m1_sp + m1_wid/2
double outX = StdCellParams.getRightDiffX(nmos, pmos) + 2 + 3 + 2;
LayoutLib.newExport(inv, "out", PortCharacteristic.OUT,
tech.m1(), 4, outX, 0);
// create vdd and gnd exports and connect to MOS source/drains
stdCell.wireVddGnd(pmos, StdCellParams.EVEN, inv);
boolean weakNmosOneFold = fwW.nbFolds==1;
stdCell.wireVddGnd(new FoldedMos[] {nmosW, nmos},
weakNmosOneFold ? flipWeakMos : StdCellParams.EVEN,
inv);
// Connect gates of weak MOS using poly
TrackRouter weakPoly = new TrackRouterH(tech.p1(), 2, 0, tech, inv);
for (int i=0; i<nmosW.nbGates(); i++) {
weakPoly.connect(nmosW.getGate(i, 'T'));
}
// Connect an equal number of NMOS gates as weak PMOS gates
for (int i=0; i<Math.min(pmos.nbGates(), nmosW.nbGates()); i++) {
weakPoly.connect(pmos.getGate(i, 'B'));
}
// Connect gates using metal1 along bottom of cell
double gndBot = stdCell.getGndY() - stdCell.getGndWidth() / 2;
double inLoFromGnd = gndBot - 3 - 2; // -m1_m1_sp -m1_wid/2
double nmosBot = nmosY - fwN.physWid / 2;
double inLoFromMos = nmosBot - 2 - 2.5; // -nd_p1_sp - p1m1_wid/2
double inLoY = Math.min(inLoFromGnd, inLoFromMos);
LayoutLib.newExport(inv, "in[n]", PortCharacteristic.IN, tech.m1(),
4, inNX, outLoY);
PortInst m1pin = LayoutLib.newNodeInst(tech.m1pin(), pmosX, outLoY, 4, 4, 0,
inv).getOnlyPortInst();
TrackRouter inNHi = new TrackRouterH(tech.m2(), 3, outLoY, tech, inv);
inNHi.connect(inv.findExport("in[n]"));
inNHi.connect(m1pin);
TrackRouter inLo = new TrackRouterH(tech.m1(), 3, inLoY, tech, inv);
inLo.connect(m1pin);
for (int i=0; i<nmos.nbGates(); i++) {
inLo.connect(nmos.getGate(i, 'B'));
}
// Connect gates using metal1 along top of cell
double vddTop = stdCell.getVddY() + stdCell.getVddWidth() / 2;
double inHiFromVdd = vddTop + 3 + 2; // +m1_m1_sp + m1_wid/2
double pmosTop = pmosY + fwP.physWid / 2;
double inHiFromMos = pmosTop + 2 + 2.5; // +pd_p1_sp + p1m1_wid/2
double inHiY = Math.max(inHiFromVdd, inHiFromMos);
LayoutLib.newExport(inv, "in[p]", PortCharacteristic.IN, tech.m1(),
4, inPX, inHiY);
TrackRouter inHi = new TrackRouterH(tech.m1(), 3, inHiY, tech, inv);
inHi.connect(inv.findExport("in[p]"));
for (int i=0; i<pmos.nbGates(); i++) {
inHi.connect(pmos.getGate(i, 'T'));
}
// connect up output
TrackRouter out = new TrackRouterH(tech.m1(), outBusWidth, outY, tech, inv);
out.connect(inv.findExport("out"));
for (int i=(weakNmosOneFold?0:1); i<nmosW.nbSrcDrns(); i+=2) {
out.connect(nmosW.getSrcDrn(i));
}
for (int i=1; i<pmos.nbSrcDrns(); i+=2) {
out.connect(pmos.getSrcDrn(i));
}
for (int i=1; i<nmos.nbSrcDrns(); i+=2) {
out.connect(nmos.getSrcDrn(i));
}
// add wells
double wellMinX = 0;
double wellMaxX = outX + outBusWidth/2 + 1.5; // m1_wid/2 + m1m1_space/2
stdCell.addNmosWell(wellMinX, wellMaxX, inv);
stdCell.addPmosWell(wellMinX, wellMaxX, inv);
// add essential bounds
stdCell.addEssentialBounds(wellMinX, wellMaxX, inv);
// perform Network Consistency Check
stdCell.doNCC(inv, nm+"{sch}");
return inv;
}
}