/* -*- tab-width: 4 -*-
*
* Electric(tm) VLSI Design System
*
* File: Nand3_star_en_sy3.java
*
* Copyright (c) 2003, Oracle and/or its affiliates. All rights reserved.
*
* Electric(tm) is free software; you can redistribute it and/or modify
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* 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.
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* You should have received a copy of the GNU General Public License
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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;
class Nand3_star_en_sy3 {
private static final double DEF_SIZE = LayoutLib.DEF_SIZE;
private static final double nmosTop = -9.0;
private static final double pmosBot = 9.0;
// private static final double wellOverhangDiff = 6;
private static final double incY = -4.0;
private static final double inbY = 4.0;
private static final double outHiY = 11.0;
private static final double outLoY = -11.0;
private static void error(boolean pred, String msg) {
Job.error(pred, msg);
}
static Cell makePart(double sz, String threshold,
StdCellParams stdCell) {
TechType tech = stdCell.getTechType();
sz = stdCell.roundSize(sz);
error(!threshold.equals("") && !threshold.equals("LT"),
"Nand3en_sy3: threshold not \"\" or \"LT\": "+threshold);
String nm = "nand3" + threshold + "en_sy3";
// Stack the 2 strong PMOSs above the symmetric NMOS stack
// Compute the number of folds and width for the 2 strong PMOSs.
double spaceAvail = // p1_p1_sp/2 + p1m1_wid + p1pd_sp
stdCell.getCellTop() - (1.5 + 5 + 2) - pmosBot;
double lamPerSz = threshold.equals("LT") ? 2 : 6;
double totWid = sz * lamPerSz * 2; // 2 independent pullups
FoldsAndWidth fwP = stdCell.calcFoldsAndWidth(spaceAvail, totWid, 2);
error(fwP==null, "can't make "+nm+" this small: "+sz);
// Shift weak PMOS up so the lower edge of it's gate clears any p1m1.
// Compute the number of folds and width for the weak PMOS.
totWid = Math.max(5, sz * lamPerSz / 10);
// p1m1_wid/2 + p1_p1_sp + gateOverhangDiff
double weakBot = inbY + 2.5 + 3 + 2;
spaceAvail = spaceAvail + pmosBot - weakBot;
FoldsAndWidth fwW = stdCell.calcFoldsAndWidth(spaceAvail, totWid, 1);
error(fwW==null,
"can't make "+nm+" weak PMOS should never have a problem");
// Compute number of folds and width for NMOS
int nbStackedN = 3;
// p1OverhangDiff + p1_p1_sp + p1m1_wid + p1_p1_sp/2
spaceAvail = nmosTop - (stdCell.getCellBot() + 2 + 3 + 5 + 1.5);
totWid = sz * 3 * nbStackedN;
FoldsAndWidth fwN = stdCell.calcFoldsAndWidth(spaceAvail, totWid, 3);
error(fwN==null, "can't make "+nm+" this small: "+sz);
// create NAND Part
Cell nand = stdCell.findPart(nm, sz);
if (nand!=null) return nand;
nand = stdCell.newPart(nm, sz);
// leave vertical m1 tracks for ina, inC, and inc jog
double inbX = 1.5 + 2; // m1_m1_sp/2 + m1_wid/2
double incX = inbX + 2 + 3 + 2; // m1_wid/2 + m1_m1_sp + m1_wid/2
double jogbX = incX + 2 + 3 + 2; // m1_wid/2 + m1_m1_sp + m1_wid/2
double nmosX = jogbX + 2 + 3 + 2;//m1_wid/2 + m1_m1_sp + diffCont_wid/2
// NMOS
FoldedMos nmos = new FoldedNmos(nmosX, nmosTop - fwN.physWid/2,
fwN.nbFolds, nbStackedN, fwN.gateWid,
nand, tech);
// PMOS
// pmos pitch for 12 folds: 8 * 12 = 96
// nmos pitch for 6 folds: (3 * 5 + 3) * 6 = 108
// Create one FoldedMos for every 12 folds.
// Center 12 pmos folds over 6 nmos folds
double pmosY = pmosBot + fwP.physWid/2;
FoldedMos[] pmoss = new FoldedMos[(int) Math.ceil(fwP.nbFolds/12.0)];
for (int i=0; i<pmoss.length; i++) {
double pmosPitch = 108;
double pmosX = nmosX + 6 + i*pmosPitch;
int nbFolds = Math.min(12, fwP.nbFolds - i*12);
pmoss[i] = new FoldedPmos(pmosX, pmosY, nbFolds, 1, fwP.gateWid,
nand, tech);
}
// Create one FoldedMos for weak PMOS
double weakX = StdCellParams.getRightDiffX(pmoss) + 12;// for now don't share
double weakY = weakBot + fwW.physWid/2;
FoldedMos weak = new FoldedPmos(weakX, weakY, fwW.nbFolds, 1,
fwW.gateWid, nand, tech);
// create an array that holds all PMOS, strong and weak
FoldedMos[] stroWeakPmoss = new FoldedMos[pmoss.length+1];
for (int i=0; i<pmoss.length; i++) {
stroWeakPmoss[i] = pmoss[i];
}
stroWeakPmoss[pmoss.length] = weak;
// create vdd and gnd exports and connect to MOS source/drains
stdCell.wireVddGnd(nmos, StdCellParams.EVEN, nand);
stdCell.wireVddGnd(stroWeakPmoss, StdCellParams.EVEN, nand);
// Nand input B
double inbHiY = 11;
LayoutLib.newExport(nand, "inb", PortCharacteristic.IN, tech.m1(),
4, inbX, inbHiY);
TrackRouter inbHi = new TrackRouterH(tech.m2(), 3, inbHiY, tech, nand);
inbHi.connect(nand.findExport("inb"));
PortInst jogb = LayoutLib.newNodeInst(tech.m1pin(), jogbX, inbHiY,
DEF_SIZE, DEF_SIZE, 0, nand
).getOnlyPortInst();
inbHi.connect(jogb);
TrackRouter inbLo = new TrackRouterH(tech.m1(), 3, inbY, tech, nand);
inbLo.connect(jogb);
for (int i=0; i<fwN.nbFolds; i++) {
switch (i%6) {
case 0: inbLo.connect(nmos.getGate(i*3+0, 'T'), 1.5); break;
case 1: inbLo.connect(nmos.getGate(i*3+1, 'T'), -1); break;
case 2: inbLo.connect(nmos.getGate(i*3+2, 'T')); break;
case 3: inbLo.connect(nmos.getGate(i*3+0, 'T')); break;
case 4: inbLo.connect(nmos.getGate(i*3+1, 'T'), 1); break;
case 5: inbLo.connect(nmos.getGate(i*3+2, 'T'), -1.5); break;
}
}
for (int i=0; i<pmoss.length; i++) {
for (int j=0; j<pmoss[i].nbGates(); j++) {
switch (j%12) {
case 0: inbLo.connect(pmoss[i].getGate(j, 'B'), -4.5, 1.5);
break;
case 2: inbLo.connect(pmoss[i].getGate(j, 'B')); break;
case 5: inbLo.connect(pmoss[i].getGate(j, 'B')); break;
case 6: inbLo.connect(pmoss[i].getGate(j, 'B')); break;
case 9: inbLo.connect(pmoss[i].getGate(j, 'B')); break;
case 11: inbLo.connect(pmoss[i].getGate(j, 'B'), 4.5, 1.5);
break;
}
}
}
// Nand input A
// m1_wid + m1_space + m1_wid/2
double inaX = StdCellParams.getRightDiffX(nmos) + 2 + 3 + 2;
double gndBot = stdCell.getGndY() - stdCell.getGndWidth()/2;
double inaLoY = gndBot - 3 - 2; // -m1_m1_sp -m1_wid/2
// -polyOverhangDiff - p1_p1_sp -p1m1/2
double nmosBot = nmosTop - fwN.physWid;
inaLoY = Math.min(inaLoY, nmosBot - 2 - 3 - 2.5);
double vddTop = stdCell.getVddY() + stdCell.getVddWidth()/2;
double weakTop = weakBot + fwW.physWid;
// -m1_m1_sp -m1_wid/2
double inaHiY = Math.max(vddTop, weakTop) + 3 + 2;
LayoutLib.newExport(nand, "ina", PortCharacteristic.IN, tech.m1(),
4, inaX, inaHiY);
TrackRouter inaHi = new TrackRouterH(tech.m1(), 3, inaHiY, tech, nand);
inaHi.connect(nand.findExport("ina"));
for (int i=0; i<weak.nbGates(); i++) {
inaHi.connect(weak.getGate(i, 'T'));
}
TrackRouter inaLo = new TrackRouterH(tech.m1(), 3, inaLoY, tech, nand);
inaLo.connect(nand.findExport("ina"));
for (int i=0; i<fwN.nbFolds; i++) {
switch (i%6) {
case 0: inaLo.connect(nmos.getGate(i*3+1, 'B')); break;
case 1: inaLo.connect(nmos.getGate(i*3+0, 'B')); break;
case 2: inaLo.connect(nmos.getGate(i*3+0, 'B')); break;
case 3: inaLo.connect(nmos.getGate(i*3+2, 'B')); break;
case 4: inaLo.connect(nmos.getGate(i*3+2, 'B')); break;
case 5: inaLo.connect(nmos.getGate(i*3+1, 'B')); break;
}
}
// Nand input C
TrackRouter inc = new TrackRouterH(tech.m1(), 3, incY, tech, nand);
for (int i=0; i<fwN.nbFolds; i++) {
switch (i%6) {
case 0: inc.connect(nmos.getGate(i*3+2, 'T'), 1.5); break;
case 1: inc.connect(nmos.getGate(i*3+2, 'T'), 1.5);break;
case 2: inc.connect(nmos.getGate(i*3+1, 'T'), -11.5, 1);break;
case 3: inc.connect(nmos.getGate(i*3+1, 'T'), 11.5, 1);break;
case 4: inc.connect(nmos.getGate(i*3+0, 'T'), -1.5);break;
case 5: inc.connect(nmos.getGate(i*3+0, 'T'), -1.5); break;
}
}
for (int i=0; i<pmoss.length; i++) {
for (int j=0; j<pmoss[i].nbGates(); j++) {
switch (j%12) {
case 1: inc.connect(pmoss[i].getGate(j, 'B'), -2.5, 3.5);
break;
case 3: inc.connect(pmoss[i].getGate(j, 'B'), -.5); break;
case 4: inc.connect(pmoss[i].getGate(j, 'B'), -8.5, 3); break;
case 7: inc.connect(pmoss[i].getGate(j, 'B'), 8.5, 3); break;
case 8: inc.connect(pmoss[i].getGate(j, 'B'), .5); break;
case 10: inc.connect(pmoss[i].getGate(j, 'B'), 2.5, 3.5);
break;
}
}
}
LayoutLib.newExport(nand, "inc", PortCharacteristic.IN, tech.m1(),
4, incX, incY);
inc.connect(nand.findExport("inc"));
// Nand output
double outX = inaX + 2 + 3 + 2; // m1_wid/2 + m1_sp + m1_wid/2
LayoutLib.newExport(nand, "out", PortCharacteristic.OUT, tech.m1(),
4, outX, outHiY);
TrackRouter outHi = new TrackRouterH(tech.m2(), 4, outHiY, tech, nand);
outHi.connect(nand.findExport("out"));
for (int i=0; i<stroWeakPmoss.length; i++) {
for (int j=1; j<stroWeakPmoss[i].nbSrcDrns(); j+=2) {
outHi.connect(stroWeakPmoss[i].getSrcDrn(j));
}
}
TrackRouter outLo = new TrackRouterH(tech.m2(), 4, outLoY, tech, nand);
outLo.connect(nand.findExport("out"));
for (int i=1; i<nmos.nbSrcDrns(); i+=2) {
outLo.connect(nmos.getSrcDrn(i));
}
// add wells
double wellMinX = 0;
double wellMaxX = outX + 2 + 1.5; // m1_wid/2 + m1m1_space/2
stdCell.addNmosWell(wellMinX, wellMaxX, nand);
stdCell.addPmosWell(wellMinX, wellMaxX, nand);
// add essential bounds
stdCell.addEssentialBounds(wellMinX, wellMaxX, nand);
// perform Network Consistency Check
// RKao fixme. NCC with "wrong" schematic
stdCell.doNCC(nand, nm+"{sch}");
return nand;
}
}