+++ /dev/null
-package edu.berkeley.slipway.mpar;
-import com.atmel.fpslic.*;
-import byucc.edif.tools.merge.*;
-import byucc.edif.*;
-import java.io.*;
-import java.util.*;
-import edu.berkeley.slipway.*;
-import com.atmel.fpslic.*;
-import static com.atmel.fpslic.FpslicConstants.*;
-import static edu.berkeley.slipway.mpar.MPARDemo.*;
-
-public class FlatNetlist {
-
- private HashMap<String,Integer> ids = new HashMap<String,Integer>();
-
- public HashSet<Node> nodes = new HashSet<Node>();
- public HashSet<Net> nets = new HashSet<Net>();
-
- /** a node is some primitive element; a potential configuration of a CLB */
- public class Node {
- public PhysicalDevice.PhysicalCell physicalCell = null;
- private final String type;
- private final int id;
-
- public int x = -1;
- public int y = -1;
-
- private HashMap<String,Port> ports = new HashMap<String,Port>();
-
- public Node(String type) {
- nodes.add(this);
- this.type = type.toLowerCase();
- Integer num = ids.get(type);
- this.id = num == null ? 0 : num.intValue();
- ids.put(type, this.id+1);
- }
- public String getType() { return type; }
- public String toString() {
- if (x==-1 || y==-1)
- return type + "["+id+"]";
- return type + "@("+x+","+y+")";
- }
- public Port getPort(String name, boolean driver) {
- Port p = ports.get(name);
- if (p==null) ports.put(name, p = new Port(name, driver));
- return p;
- }
-
- public Fpslic.Cell getPlacement(Fpslic fpslic) { return fpslic.cell(x, y); }
- public void place(Fpslic fpslic) {
- Fpslic.Cell cell = fpslic.cell(x,y);
- cell.c(XLUT);
- cell.b(false);
- cell.f(false);
- cell.xi(NW);
- cell.yi(EAST);
- if (type.equals("and2")) cell.xlut(LUT_SELF & LUT_OTHER);
- else if (type.equals("or2")) cell.xlut(LUT_SELF | LUT_OTHER);
- else if (type.equals("xor2")) cell.xlut(LUT_SELF ^ LUT_OTHER);
- else if (type.equals("buf")) cell.xlut(LUT_SELF);
- else if (type.equals("inv")) cell.xlut(~LUT_SELF);
- else if (type.equals("cell0")) return;
- }
-
- private int portIndex = 0;
-
- /** a port is an input or output to a Node */
- public class Port {
- private final String name;
- private final boolean driver;
- Net net;
- public final int index;
- public Port(String name, boolean driver) {
- this.name = name;
- this.driver = driver;
- this.index = driver ? 0 : portIndex++;
- }
- public String toString() { return Node.this + "." + name; }
- public Node getNode() { return Node.this; }
- public void connect(Port p) {
- if (net != null) { net.add(p);
- } else if (p.net != null) { p.net.add(this);
- } else {
- new Net().add(this);
- this.net.add(p);
- }
- }
- public void route(Fpslic fpslic, Port[] dests, PhysicalDevice pd, FlatNetlist.Net owner) {
- PhysicalDevice.PhysicalNet[] destsp = new PhysicalDevice.PhysicalNet[dests.length];
- for(int i=0; i<dests.length; i++) {
- Port dest = dests[i];
- switch(dest.index) {
- case 0: destsp[i] = dest.getNode().physicalCell.getNet("xi"); break;
- case 1: destsp[i] = dest.getNode().physicalCell.getNet("yi"); break;
- default: throw new Error();
- }
- }
- //System.out.println(physicalCell.getNet("out"));
- //System.out.println(destsp[0]);
- pd.route(physicalCell.getNet("out"), destsp, owner);
-
- /*
- Fpslic.Cell driverCell = fpslic.cell(getNode().x,getNode().y);
- Fpslic.Cell destCell = fpslic.cell(dest.getNode().x,dest.getNode().y);
- boolean[] hblocked = new boolean[5];
- boolean[] vblocked = new boolean[5];
- hblocked[3] = true;
- vblocked[3] = true;
- int minx = Math.min(getNode().x, dest.getNode().x);
- int miny = Math.min(getNode().y, dest.getNode().y);
- int maxx = Math.max(getNode().x, dest.getNode().x);
- int maxy = Math.max(getNode().y, dest.getNode().y);
- for(int cx = 0; cx <= 3; cx++) {
- Fpslic.Cell c = fpslic.cell(cx, getNode().y);
- for(int i=0; i<5; i++)
- hblocked[i] |= (c.hx(i) && !c.equals(driverCell));
- }
- for(int cy = 0; cy <= 3; cy++) {
- Fpslic.Cell c = fpslic.cell(dest.getNode().x, cy);
- for(int i=0; i<5; i++)
- vblocked[i] |= (c.vx(i) && !c.equals(driverCell));
- }
- int free = 0;
- for(; free < 5; free++) if (!hblocked[free]) break;
- for(; free < 5; free++) if (!vblocked[free]) break;
- if (free >= 5) throw new RuntimeException("unroutable!");
- Fpslic.Cell turnCell = fpslic.cell(dest.getNode().x, getNode().y);
- driverCell.out(free, true);
- driverCell.h(free, true);
- turnCell.h(free, true);
- turnCell.v(free, true);
- switch(dest.index) {
- case 0: destCell.xi(L0 + free); break;
- case 1: destCell.yi(L0 + free); break;
- case 2: destCell.wi(L0 + free); break;
- case 3: destCell.zi(L0 + free); break;
- default: throw new RuntimeException("error");
- }
- destCell.v(free, true);
- System.out.println("route " + this + " -> " + dest + " on planes " + free);
- */
- }
- }
- }
-
- /** a Net is a collection of ports which are wired together */
- public class Net implements Iterable<Node.Port> {
- private Node.Port driver = null;
- private HashSet<Node.Port> ports = new HashSet<Node.Port>();
- public Net() { nets.add(this); }
- public Iterator<Node.Port> iterator() { return ports.iterator(); }
- public int getSize() { return ports.size(); }
- public HashSet<PhysicalDevice.PhysicalPip> pips = new HashSet<PhysicalDevice.PhysicalPip>();
- public HashSet<PhysicalDevice.PhysicalNet> pns = new HashSet<PhysicalDevice.PhysicalNet>();
- public boolean routed = false;
- public void unroute() {
- for(PhysicalDevice.PhysicalPip pip : pips)
- pip.set(false);
- for(PhysicalDevice.PhysicalNet net : pns) {
- net.owners.remove(this);
- net.load--;
- }
- pips.clear();
- pns.clear();
- routed = false;
- }
- public void route(Fpslic fpslic, PhysicalDevice pd) {
- if (driver == null) return;
- if (routed) return;
- //System.out.println();
- //System.out.println("routing " + this);
- Node.Port[] dests = new Node.Port[ports.size() - (ports.contains(driver) ? 1 : 0)];
- int i = 0;
- for(Node.Port p : ports)
- if (p != driver)
- dests[i++] = p;
- driver.route(fpslic, dests, pd, this);
- routed = true;
- }
- public void add(Node.Port p) {
- if (p.driver) {
- if (driver != null && driver != p)
- throw new RuntimeException("two drivers on a port!\n "+driver+"\n "+p);
- driver = p;
- }
- if (p.net==this || ports.contains(p)) return;
- ports.add(p);
- add(p.net);
- p.net = this;
- }
- public void add(Net n) {
- if (n==this || n==null) return;
- for(Node.Port p : n) add(p);
- nets.remove(n);
- }
- public String toString() {
- StringBuffer ret = new StringBuffer();
- ret.append(driver==null ? "()" : driver.toString());
- ret.append(" -> ");
- for(Node.Port p : this)
- if (p!=driver)
- ret.append(p+" ");
- return ret.toString();
- }
- }
-
-
- public HashMap<EdifCellInstance,FlatNetlist.Node> cache =
- new HashMap<EdifCellInstance,FlatNetlist.Node>();
- public HashMap<String,FlatNetlist.Node> top =
- new HashMap<String,FlatNetlist.Node>();
-
- public FlatNetlist.Node createNode(EdifCellInstance eci, String portName) {
- FlatNetlist.Node n = eci==null ? top.get(portName) : cache.get(eci);
- if (n != null) return n;
- if (eci==null) {
- n = new FlatNetlist.Node("top_"+portName);
- top.put(portName, n);
- return n;
- } else {
- n = new FlatNetlist.Node(eci.getType());
- cache.put(eci,n);
- }
- for(EdifPortRef epr : eci.getAllEPRs()) {
- EdifPort ep = epr.getPort();
- EdifNet en = epr.getNet();
- String name = ep.getOldName();
- boolean driver = ep.getDirection()==ep.OUT;
- if (eci==null) driver = !driver;
- if (eci==null) name = driver ? "out" : "xi";
- FlatNetlist.Node.Port p = n.getPort(name, driver);
- for(EdifPortRef epr2 : en.getConnectedPortRefs()) {
- EdifCellInstance eci2 = epr2.getCellInstance();
- EdifPort ep2 = epr2.getPort();
- Node n2 = createNode(eci2, ep2.getOldName());
- driver = ep2.getDirection()==ep.OUT;
- name = ep2.getOldName();
- if (eci2==null) driver = !driver;
- if (eci2==null) name = driver ? "out" : "xi";
- FlatNetlist.Node.Port p2 = n2.getPort(name, driver);
- p.connect(p2);
- }
- }
- return n;
- }
-}
EdifLibrary initLib = new EdifLibrary(elm, "initLib");
EdifEnvironment env = EdifMergeParser.parseAndMerge(s, initLib);
System.out.println("top is " + env.getTopCell());
- FlatNetlist fnl = new FlatNetlist();
+ NetList fnl = new NetList();
for(Iterator<EdifCellInstance> it = (Iterator<EdifCellInstance>)env.getTopCell().cellInstanceIterator();
it.hasNext();
) {
- FlatNetlist.Node n = fnl.createNode(it.next(), null);
+ NetList.Node n = fnl.createNode(it.next(), null);
}
Fpslic fpslic = new FtdiBoard();
- PhysicalDevice pd = new PhysicalDevice(fpslic, 20, 20);
+ int width = 20;
+ int height = 20;
+ PhysicalDevice pd = new PhysicalFpslic(fpslic, width, height);
int px = 0;
int py = 0;
// crude map
Random rand = new Random();
- boolean[][] used = new boolean[pd.width][pd.height];
- for(FlatNetlist.Node n : fnl.nodes) {
+ boolean[][] used = new boolean[width][height];
+ for(NetList.Node n : fnl.nodes) {
while(true) {
- px = Math.abs(rand.nextInt()) % pd.width;
- py = Math.abs(rand.nextInt()) % pd.height;
+ px = Math.abs(rand.nextInt()) % width;
+ py = Math.abs(rand.nextInt()) % height;
if (!used[px][py]) {
used[px][py] = true;
- n.x = px;
- n.y = py;
- n.physicalCell = pd.getCell(px, py);
System.out.println("placed " + n + " at ("+px+","+py+")");
- n.place(fpslic);
+ pd.getCell(px, py).place(n);
break;
}
}
}
int trial = 0;
- HashSet<FlatNetlist.Net> needUnroute = new HashSet<FlatNetlist.Net>();
+ HashSet<NetList.LogicalNet> needUnroute = new HashSet<NetList.LogicalNet>();
while(true) {
System.out.println();
System.out.println("routing trial " + (++trial));
- for(FlatNetlist.Net net : fnl.nets) {
+ for(NetList.LogicalNet net : fnl.nets) {
if (net.getSize() <= 1) continue;
net.route(fpslic, pd);
}
double congestion = 0;
int overrouted = 0;
needUnroute.clear();
- for(PhysicalDevice.PhysicalNet pn : pd.allPhysicalNets) {
- if (pn.load > 1) {
- //System.out.println("overrouted: " + pn + ", congestion="+pn.congestion + ", load=" + pn.load);
+ for(PhysicalDevice.PhysicalNet pn : pd) {
+ if (pn.isCongested()) {
overrouted++;
- congestion += pn.congestion;
+ congestion += pn.getCongestion();
}
- pn.congestion = pn.congestion * alphaParameter;
- if (pn.load > 1) {
- pn.congestion += betaParameter;
- // don't do this here
- //pn.congestion += betaParameter;
- for(FlatNetlist.Net n : pn.owners)
+ pn.updateCongestion();
+ if (pn.isCongested())
+ for(NetList.LogicalNet n : pn.getLogicalNets())
needUnroute.add(n);
- }
}
- System.out.println(" overrouted="+overrouted+", congestion="+congestion +", ripping up " + needUnroute.size() +" nets of " + fnl.nets.size());
+ System.out.println(" overrouted="+overrouted+", congestion="+congestion +
+ ", ripping up " + needUnroute.size() +" nets of " + fnl.nets.size());
if (overrouted <= 0) break;
- //for(FlatNetlist.Net net : fnl.nets)
- for(FlatNetlist.Net net : needUnroute)
- net.unroute();
- /*
- for(PhysicalDevice.PhysicalNet pn : pd.allPhysicalNets)
- for(PhysicalDevice.PhysicalPip pip : pn) {
- pip.set(false);
- }
- */
+ for(NetList.LogicalNet net : needUnroute) net.unroute();
}
// set up scan cell
fpslic.iob_right(0, true).enableOutput(WEST);
fpslic.flush();
- int width = 8;
+ int xwidth = 8;
while(true) {
- int a = Math.abs(rand.nextInt()) % (1 << width);
- int b = Math.abs(rand.nextInt()) % (1 << width);
+ int a = Math.abs(rand.nextInt()) % (1 << xwidth);
+ int b = Math.abs(rand.nextInt()) % (1 << xwidth);
setInput(fnl, fpslic, "a", a);
setInput(fnl, fpslic, "b", b);
setInput(fnl, fpslic, "ci", 0);
}
- public static void setInput(FlatNetlist fnl, Fpslic fpslic, String prefix, int val) {
+ public static void setInput(NetList fnl, Fpslic fpslic, String prefix, int val) {
for(int i=0; ; i++) {
- FlatNetlist.Node n = fnl.top.get(prefix + "["+i+"]");
+ NetList.Node n = fnl.top.get(prefix + "["+i+"]");
if (n==null && i==0) n = fnl.top.get(prefix);
if (n==null) return;
Fpslic.Cell c = n.getPlacement(fpslic);
val = val >> 1;
}
}
- public static int getOutput(FlatNetlist fnl, Fpslic fpslic, String prefix) {
+ public static int getOutput(NetList fnl, Fpslic fpslic, String prefix) {
int val = 0;
for(int i=0; ; i++) {
- FlatNetlist.Node n = fnl.top.get(prefix+"["+i+"]");
+ NetList.Node n = fnl.top.get(prefix+"["+i+"]");
if (n==null && i==0) n = fnl.top.get(prefix);
if (n==null) return val;
Fpslic.Cell c = n.getPlacement(fpslic);
--- /dev/null
+package edu.berkeley.slipway.mpar;
+import com.atmel.fpslic.*;
+import byucc.edif.tools.merge.*;
+import byucc.edif.*;
+import java.io.*;
+import java.util.*;
+import edu.berkeley.slipway.*;
+import com.atmel.fpslic.*;
+import static com.atmel.fpslic.FpslicConstants.*;
+import static edu.berkeley.slipway.mpar.MPARDemo.*;
+
+public class NetList {
+
+ private HashMap<String,Integer> ids = new HashMap<String,Integer>();
+
+ public HashSet<Node> nodes = new HashSet<Node>();
+ public HashSet<LogicalNet> nets = new HashSet<LogicalNet>();
+
+ /** a node is some primitive element; a potential configuration of a CLB */
+ public class Node {
+ public PhysicalDevice.PhysicalCell physicalCell = null;
+ private final String type;
+ private final int id;
+
+ public int x = -1;
+ public int y = -1;
+
+ private HashMap<String,Port> ports = new HashMap<String,Port>();
+
+ public Node(String type) {
+ nodes.add(this);
+ this.type = type.toLowerCase();
+ Integer num = ids.get(type);
+ this.id = num == null ? 0 : num.intValue();
+ ids.put(type, this.id+1);
+ }
+ public String getType() { return type; }
+ public String toString() {
+ if (x==-1 || y==-1)
+ return type + "["+id+"]";
+ return type + "@("+x+","+y+")";
+ }
+ public Port getPort(String name, boolean driver) {
+ Port p = ports.get(name);
+ if (p==null) ports.put(name, p = new Port(name, driver));
+ return p;
+ }
+
+ public Fpslic.Cell getPlacement(Fpslic fpslic) { return fpslic.cell(x, y); }
+
+ private int portIndex = 0;
+
+ /** a port is an input or output to a Node */
+ public class Port {
+ private final String name;
+ private final boolean driver;
+ LogicalNet net;
+ public final int index;
+ public Port(String name, boolean driver) {
+ this.name = name;
+ this.driver = driver;
+ this.index = driver ? 0 : portIndex++;
+ }
+ public String toString() { return Node.this + "." + name; }
+ public Node getNode() { return Node.this; }
+ public void connect(Port p) {
+ if (net != null) { net.add(p);
+ } else if (p.net != null) { p.net.add(this);
+ } else {
+ new LogicalNet().add(this);
+ this.net.add(p);
+ }
+ }
+ }
+ }
+
+ /** a Net is a collection of ports which are wired together */
+ public class LogicalNet implements Iterable<Node.Port> {
+ private Node.Port driver = null;
+ private HashSet<Node.Port> ports = new HashSet<Node.Port>();
+ private HashSet<PhysicalDevice.PhysicalPip> pips = new HashSet<PhysicalDevice.PhysicalPip>();
+ private HashSet<PhysicalDevice.PhysicalNet> pns = new HashSet<PhysicalDevice.PhysicalNet>();
+
+ public void addPhysicalNet(PhysicalDevice.PhysicalNet pn) { pns.add(pn); }
+ public void removePhysicalNet(PhysicalDevice.PhysicalNet pn) { pns.remove(pn); }
+ public void addPhysicalPip(PhysicalDevice.PhysicalPip pip) { pips.add(pip); }
+
+ public LogicalNet() { nets.add(this); }
+ public Iterator<Node.Port> iterator() { return ports.iterator(); }
+ public int getSize() { return ports.size(); }
+ public boolean routed = false;
+ public void unroute() {
+ for(PhysicalDevice.PhysicalPip pip : pips) pip.set(false);
+ while(pns.size() > 0) pns.iterator().next().removeLogicalNet(this);
+ pips.clear();
+ pns.clear();
+ routed = false;
+ }
+ public void route(Fpslic fpslic, PhysicalDevice pd) {
+ if (driver == null) return;
+ if (routed) return;
+ Node.Port[] dests = new Node.Port[ports.size() - (ports.contains(driver) ? 1 : 0)];
+ int j = 0;
+ for(Node.Port p : ports)
+ if (p != driver)
+ dests[j++] = p;
+ PhysicalDevice.PhysicalNet[] destsp = new PhysicalDevice.PhysicalNet[dests.length];
+ for(int i=0; i<dests.length; i++) {
+ Node.Port dest = dests[i];
+ switch(dest.index) {
+ case 0: destsp[i] = dest.getNode().physicalCell.getNet("xi"); break;
+ case 1: destsp[i] = dest.getNode().physicalCell.getNet("yi"); break;
+ default: throw new Error();
+ }
+ }
+ driver.getNode().physicalCell.getNet("out").route(destsp, this);
+ routed = true;
+ }
+ public void add(Node.Port p) {
+ if (p.driver) {
+ if (driver != null && driver != p)
+ throw new RuntimeException("two drivers on a port!\n "+driver+"\n "+p);
+ driver = p;
+ }
+ if (p.net==this || ports.contains(p)) return;
+ ports.add(p);
+ add(p.net);
+ p.net = this;
+ }
+ public void add(LogicalNet n) {
+ if (n==this || n==null) return;
+ for(Node.Port p : n) add(p);
+ nets.remove(n);
+ }
+ public String toString() {
+ StringBuffer ret = new StringBuffer();
+ ret.append(driver==null ? "()" : driver.toString());
+ ret.append(" -> ");
+ for(Node.Port p : this)
+ if (p!=driver)
+ ret.append(p+" ");
+ return ret.toString();
+ }
+ }
+
+
+ public HashMap<EdifCellInstance,NetList.Node> cache =
+ new HashMap<EdifCellInstance,NetList.Node>();
+ public HashMap<String,NetList.Node> top =
+ new HashMap<String,NetList.Node>();
+
+ public NetList.Node createNode(EdifCellInstance eci, String portName) {
+ NetList.Node n = eci==null ? top.get(portName) : cache.get(eci);
+ if (n != null) return n;
+ if (eci==null) {
+ n = new NetList.Node("top_"+portName);
+ top.put(portName, n);
+ return n;
+ } else {
+ n = new NetList.Node(eci.getType());
+ cache.put(eci,n);
+ }
+ for(EdifPortRef epr : eci.getAllEPRs()) {
+ EdifPort ep = epr.getPort();
+ EdifNet en = epr.getNet();
+ String name = ep.getOldName();
+ boolean driver = ep.getDirection()==ep.OUT;
+ if (eci==null) driver = !driver;
+ if (eci==null) name = driver ? "out" : "xi";
+ NetList.Node.Port p = n.getPort(name, driver);
+ for(EdifPortRef epr2 : en.getConnectedPortRefs()) {
+ EdifCellInstance eci2 = epr2.getCellInstance();
+ EdifPort ep2 = epr2.getPort();
+ Node n2 = createNode(eci2, ep2.getOldName());
+ driver = ep2.getDirection()==ep.OUT;
+ name = ep2.getOldName();
+ if (eci2==null) driver = !driver;
+ if (eci2==null) name = driver ? "out" : "xi";
+ NetList.Node.Port p2 = n2.getPort(name, driver);
+ p.connect(p2);
+ }
+ }
+ return n;
+ }
+}
package edu.berkeley.slipway.mpar;
-import com.atmel.fpslic.*;
import byucc.edif.tools.merge.*;
import byucc.edif.*;
import java.io.*;
import java.util.*;
import edu.berkeley.slipway.*;
-import com.atmel.fpslic.*;
-import static com.atmel.fpslic.FpslicConstants.*;
import static edu.berkeley.slipway.mpar.MPARDemo.*;
-public class PhysicalDevice {
- private final Fpslic fpslic;
-
- public final int width;
- public final int height;
- private final PhysicalNet[][][][] sectorWires;
- private final PhysicalCell[][] cells;
+public abstract class PhysicalDevice implements Iterable<PhysicalDevice.PhysicalNet> {
- public PhysicalCell getCell(int col, int row) {
- if (col<0) return null;
- if (row<0) return null;
- if (col>=width) return null;
- if (row>=height) return null;
- return cells[col][row];
- }
+ public abstract PhysicalCell getCell(int col, int row);
- public PhysicalDevice(final Fpslic fpslic, int width, int height) {
- this.fpslic = fpslic;
- this.width = width;
- this.height = height;
- sectorWires = new PhysicalNet[width][height][5][2];
- for(int x=0; x<width; x+=4)
- for(int y=0; y<height; y+=4)
- for(int p=0; p<5; p++) {
- for(int xc=x; xc<x+4; xc++) {
- PhysicalNet vwire = new PhysicalNet("("+xc+","+y+"-"+(y+3)+")");
- for(int yc=y; yc<y+4; yc++)
- sectorWires[xc][yc][p][0] = vwire;
- }
- for(int yc=y; yc<y+4; yc++) {
- PhysicalNet hwire = new PhysicalNet("("+x+"-"+(x+3)+","+yc+")");
- for(int xc=x; xc<x+4; xc++)
- sectorWires[xc][yc][p][1] = hwire;
- }
- }
+ private HashSet<PhysicalNet> allPhysicalNets = new HashSet<PhysicalNet>();
+ public Iterator<PhysicalNet> iterator() { return allPhysicalNets.iterator(); }
- for(int x=4; x<width; x+=4) {
- for(int y=0; y<height; y++) {
- for(int p=0; p<5; p++) {
- final int xc = x;
- final int yc = y;
- final int pc = p;
- new PhysicalPip("xxx",
- sectorWires[x-1][y][p][1],
- new PhysicalNet[] { sectorWires[x][y][p][1] },
- 5) {
- public void set(boolean connected) {
- fpslic.cell(xc-1, yc).hwire(pc).drives(fpslic.cell(xc, yc).hwire(pc), connected);
- }
- };
- new PhysicalPip("xxx",
- sectorWires[x][y][p][1],
- new PhysicalNet[] { sectorWires[x-1][y][p][1] },
- 5) {
- public void set(boolean connected) {
- fpslic.cell(xc, yc).hwire(pc).drives(fpslic.cell(xc-1, yc).hwire(pc), connected);
- }
- };
- }
- }
- }
-
- for(int x=0; x<width; x++) {
- for(int y=4; y<height; y+=4) {
- for(int p=0; p<5; p++) {
- final int xc = x;
- final int yc = y;
- final int pc = p;
- new PhysicalPip("xxx",
- sectorWires[x][y-1][p][0],
- new PhysicalNet[] { sectorWires[x][y][p][0] },
- 5) {
- public void set(boolean connected) {
- fpslic.cell(xc, yc-1).vwire(pc).drives(fpslic.cell(xc, yc).vwire(pc), connected);
- }
- };
- new PhysicalPip("xxx",
- sectorWires[x][y][p][0],
- new PhysicalNet[] { sectorWires[x][y-1][p][0] },
- 5) {
- public void set(boolean connected) {
- fpslic.cell(xc, yc).vwire(pc).drives(fpslic.cell(xc, yc-1).vwire(pc), connected);
- }
- };
- }
- }
- }
-
- cells = new PhysicalCell[width][height];
- for(int x=0; x<width; x++)
- for(int y=0; y<height; y++) {
- cells[x][y] = new PhysicalCell(x, y);
- }
- for(int x=0; x<width; x++)
- for(int y=0; y<height; y++)
- cells[x][y].link();
+ public abstract class PhysicalCell {
+ public abstract PhysicalNet getNet(String name);
+ public abstract void setFunction(String type);
+ public abstract void place(NetList.Node n);
}
- private PhysicalNet getSectorWire(int col, int row, int plane, boolean horizontal) {
- return sectorWires[col][row][plane][horizontal ? 1 : 0];
- }
-
- public class PhysicalCell {
-
- public PhysicalNet getNet(String name) {
- if (name.equals("out")) return outputNet;
- if (name.equals("xi")) return xin;
- if (name.equals("yi")) return yin;
- throw new RuntimeException("unknown");
- }
-
- private int col;
- private int row;
- private PhysicalNet outputNet;
- private PhysicalNet xin;
- private PhysicalNet yin;
- private PhysicalNet[] local = new PhysicalNet[5];
-
- private Fpslic.Cell cell() { return fpslic.cell(col, row); }
-
- public void setFunction(String type) {
- Fpslic.Cell cell = cell();
- cell.c(XLUT);
- cell.xo(false);
- cell.b(false);
- cell.f(false);
- if (type.equals("and2")) cell.xlut(LUT_SELF & LUT_OTHER);
- else if (type.equals("or2")) cell.xlut(LUT_SELF | LUT_OTHER);
- else if (type.equals("xor2")) cell.xlut(LUT_SELF ^ LUT_OTHER);
- else if (type.equals("buf")) cell.xlut(LUT_SELF);
- else if (type.equals("inv")) cell.xlut(~LUT_SELF);
- }
-
- public void link() {
- // FIXME wow, this is a horrendous hack!
- if (getCell(col-1, row+1) != null)
- new PhysicalPip(this+".xiNW", getCell(col-1, row+1).getNet("out"), new PhysicalNet[] { xin }, 5) {
- public void set(boolean connected) { cell().xi(connected ? NW : NONE); }
- };
- if (getCell(col-1, row-1) != null)
- new PhysicalPip(this+".xiSW", getCell(col-1, row-1).getNet("out"), new PhysicalNet[] { xin }, 5) {
- public void set(boolean connected) { cell().xi(connected ? SW : NONE); }
- };
- if (getCell(col+1, row+1) != null)
- new PhysicalPip(this+".xiNE", getCell(col+1, row+1).getNet("out"), new PhysicalNet[] { xin }, 5) {
- public void set(boolean connected) { cell().xi(connected ? NE : NONE); }
- };
- if (getCell(col+1, row-1) != null)
- new PhysicalPip(this+".xiSE", getCell(col+1, row-1).getNet("out"), new PhysicalNet[] { xin }, 5) {
- public void set(boolean connected) { cell().xi(connected ? SE : NONE); }
- };
- }
-
- private PhysicalCell(int col, int row) {
- this.row = row;
- this.col = col;
- outputNet = new PhysicalNet(this.toString()+".out");
- xin = new PhysicalNet(this.toString()+".xi");
- yin = new PhysicalNet(this.toString()+".yi");
- for(int j=0; j<5; j++) {
-
- // plane 3 is reserved for debugging
- if (j==3) continue;
-
- final int i = j;
- local[i] = new PhysicalNet(this.toString()+".L"+i);
- new PhysicalPip(this+".h"+i, null, new PhysicalNet[] { local[i], getSectorWire(col, row, i, true) }) {
- public void set(boolean connected) { cell().h(i, connected); }
- };
- new PhysicalPip(this+".v"+i, null, new PhysicalNet[] { local[i], getSectorWire(col, row, i, false) }) {
- public void set(boolean connected) { cell().v(i, connected); }
- };
- new PhysicalPip(this+".xi"+i, local[i], new PhysicalNet[] { xin }) {
- public void set(boolean connected) { cell().xi(connected ? i : NONE); }
- };
- new PhysicalPip(this+".yi"+i, local[i], new PhysicalNet[] { yin }) {
- public void set(boolean connected) { cell().yi(connected ? i : NONE); }
- };
- new PhysicalPip(this+".o"+i, outputNet, new PhysicalNet[] { local[i] }) {
- public void set(boolean connected) { cell().out(i, connected); }
- };
- }
- }
- public String toString() { return "cell@("+col+","+row+")"; }
+ public class PhysicalNet implements Iterable<PhysicalPip>, Comparable<PhysicalNet> {
- }
+ // per-par-iteration variables
+ private double congestion = 0;
+ private int load = 0;
- public void route(PhysicalNet source, PhysicalNet[] dests, FlatNetlist.Net owner) {
- HashSet<PhysicalNet> remainingDests = new HashSet<PhysicalNet>();
- for(PhysicalNet dest : dests) remainingDests.add(dest);
+ // temporary variables used during route searches
+ private double distance = Double.MAX_VALUE;
+ private PhysicalNet backpointer = null;
- HashSet<PhysicalNet> needsReset = new HashSet<PhysicalNet>();
- PriorityQueue<PhysicalNet> pq = new PriorityQueue<PhysicalNet>();
- needsReset.add(source);
- source.distance = 0;
- pq.add(source);
+ // adjacent pips
+ private final HashSet<PhysicalPip> pips = new HashSet<PhysicalPip>();
- OUTER: while(true) {
- PhysicalNet pn = pq.poll();
- if (pn==null) throw new Error("unroutable! " + source + " -> " + dests[0]);
- double frontier = pn.distance;
- for(PhysicalPip pip : pn)
- for(PhysicalNet net : pip.getDrivenNets()) {
- double newfrontier = frontier + 0.05 + net.congestion;
+ private String name;
- // penalty for using any net already routed in this iteration (makes routing order-sensitive)
- if (net.load >= 1) newfrontier = newfrontier + 20;
+ // logical nets currently mapped onto this physical net
+ private HashSet<NetList.LogicalNet> logicalNets = new HashSet<NetList.LogicalNet>();
- if (net.distance <= newfrontier) continue;
- pq.remove(net); // if already in there
- net.distance = newfrontier;
- pq.add(net);
- needsReset.add(net);
- net.backpointer = pn;
- if (remainingDests.contains(net)) {
- remainingDests.remove(net);
- if (remainingDests.size()==0) break OUTER;
-
- // Vaughn Betz style multiterminal routing: once we reach one sink, make every node on the path
- // "distance zero" from the source.
- for(PhysicalNet pnx = net; pnx != null; pnx = pnx.backpointer) {
- //pnx.distance = 0;
- pq.add(pnx);
- }
- break;
- }
- }
+ public double getCongestion() { return congestion; }
+ public boolean isCongested() { return load >= 2; }
+ public void updateCongestion() {
+ congestion = congestion * alphaParameter;
+ if (isCongested()) congestion += betaParameter;
}
- for(PhysicalNet dest : dests) {
- PhysicalNet pn = dest;
- while(pn != null && pn.backpointer != null) {
- pn.owners.add(owner);
- owner.pns.add(pn);
- if (pn.distance != Double.MAX_VALUE) {
- pn.distance = Double.MAX_VALUE;
- pn.load++;
- if (pn.load>=2) pn.congestion += betaParameter;
- }
- PhysicalPip pip = pn.getPipFrom(pn.backpointer);
- pip.set(true);
- owner.pips.add(pip);
- pn = pn.backpointer;
- }
- // FIXME: check pn==source at this point
+ public Iterable<NetList.LogicalNet> getLogicalNets() { return logicalNets; }
+ public void addLogicalNet(NetList.LogicalNet net) {
+ if (logicalNets.contains(net)) return;
+ logicalNets.add(net);
+ load++;
+ if (load >= 2) congestion += betaParameter;
+ net.addPhysicalNet(this);
}
-
- for(PhysicalNet pn : needsReset) {
- pn.distance = Double.MAX_VALUE;
- pn.backpointer = null;
+ public void removeLogicalNet(NetList.LogicalNet net) {
+ if (!logicalNets.contains(net)) return;
+ logicalNets.remove(net);
+ load--;
+ net.removePhysicalNet(this);
}
- }
- public HashSet<PhysicalNet> allPhysicalNets = new HashSet<PhysicalNet>();
- public class PhysicalNet implements Iterable<PhysicalPip>, Comparable<PhysicalNet> {
- public double congestion = 0;
- public int load = 0;
- public double distance = Double.MAX_VALUE;
- public PhysicalNet backpointer = null;
+ /** ordering is based on distance so we can use the Java PriorityQueue class */
public int compareTo(PhysicalNet pn) {
double x = distance - pn.distance;
return distance > pn.distance
: 0;
}
- private final HashSet<PhysicalPip> pips = new HashSet<PhysicalPip>();
public Iterator<PhysicalPip> iterator() { return pips.iterator(); }
- private String name;
public PhysicalNet(String name) {
this.name = name;
allPhysicalNets.add(this);
return pip;
return null;
}
- public HashSet<FlatNetlist.Net> owners = new HashSet<FlatNetlist.Net>();
+ public void route(PhysicalNet[] dests, NetList.LogicalNet logicalNet) {
+ HashSet<PhysicalNet> remainingDests = new HashSet<PhysicalNet>();
+ for(PhysicalNet dest : dests) remainingDests.add(dest);
+
+ HashSet<PhysicalNet> needsReset = new HashSet<PhysicalNet>();
+ PriorityQueue<PhysicalNet> pq = new PriorityQueue<PhysicalNet>();
+ needsReset.add(this);
+ this.distance = 0;
+ pq.add(this);
+
+ OUTER: while(true) {
+ PhysicalNet pn = pq.poll();
+ if (pn==null) throw new Error("unroutable! " + this + " -> " + dests[0]);
+ double frontier = pn.distance;
+ for(PhysicalPip pip : pn)
+ for(PhysicalNet net : pip.getDrivenNets()) {
+ double newfrontier = frontier + pip.getCost(pn, net) + net.getCongestion();
+
+ // penalty for using any net already routed in this iteration (makes routing order-sensitive)
+ if (net.load >= 1) newfrontier = newfrontier + 20;
+
+ if (net.distance <= newfrontier) continue;
+ pq.remove(net); // if already in there
+ net.distance = newfrontier;
+ pq.add(net);
+ needsReset.add(net);
+ net.backpointer = pn;
+
+ if (remainingDests.contains(net)) {
+ remainingDests.remove(net);
+ if (remainingDests.size()==0) break OUTER;
+ // Vaughn Betz style multiterminal routing: once we reach one sink, make every node on the path
+ // "distance zero" from the source.
+ for(PhysicalNet pnx = net; pnx != null; pnx = pnx.backpointer) {
+ pnx.distance = 0;
+ pq.add(pnx);
+ }
+ break;
+ }
+ }
+ }
+
+ for(PhysicalNet dest : dests)
+ for(PhysicalNet pn = dest; pn != null && pn.backpointer != null; pn = pn.backpointer) {
+ pn.addLogicalNet(logicalNet);
+ pn.distance = Double.MAX_VALUE;
+ PhysicalPip pip = pn.getPipFrom(pn.backpointer);
+ pip.set(true);
+ logicalNet.addPhysicalPip(pip);
+ }
+
+ for(PhysicalNet pn : needsReset) {
+ pn.distance = Double.MAX_VALUE;
+ pn.backpointer = null;
+ }
+ }
}
public abstract class PhysicalPip {
private PhysicalNet driver;
private PhysicalNet[] driven;
private String name;
- private int defaultCost;
+ private double defaultCost;
public String toString() { return name; }
public PhysicalNet getDriverNet() { return driver; }
public PhysicalNet[] getDrivenNets() { return driven; }
- public int getCost(PhysicalNet in, PhysicalNet out) { return defaultCost; }
- public PhysicalPip(String name, PhysicalNet driver, PhysicalNet[] driven) { this(name, driver, driven, 100); }
- public PhysicalPip(String name, PhysicalNet driver, PhysicalNet[] driven, int defaultCost) {
+ public double getCost(PhysicalNet in, PhysicalNet out) { return defaultCost; }
+ public PhysicalPip(String name, PhysicalNet driver, PhysicalNet[] driven) { this(name, driver, driven, 0.05); }
+ public PhysicalPip(String name, PhysicalNet driver, PhysicalNet[] driven, double defaultCost) {
this.name = name;
this.driver = driver;
this.driven = driven;
--- /dev/null
+package edu.berkeley.slipway.mpar;
+import com.atmel.fpslic.*;
+import byucc.edif.tools.merge.*;
+import byucc.edif.*;
+import java.io.*;
+import java.util.*;
+import edu.berkeley.slipway.*;
+import com.atmel.fpslic.*;
+import static com.atmel.fpslic.FpslicConstants.*;
+import static edu.berkeley.slipway.mpar.MPARDemo.*;
+
+public class PhysicalFpslic extends PhysicalDevice {
+ private final Fpslic fpslic;
+
+ public final int width;
+ public final int height;
+ private final PhysicalNet[][][][] sectorWires;
+ private final PhysicalFpslicCell[][] cells;
+
+ public PhysicalCell getCell(int col, int row) {
+ if (col<0) return null;
+ if (row<0) return null;
+ if (col>=width) return null;
+ if (row>=height) return null;
+ return cells[col][row];
+ }
+
+ public PhysicalFpslic(final Fpslic fpslic, int width, int height) {
+ this.fpslic = fpslic;
+ this.width = width;
+ this.height = height;
+ sectorWires = new PhysicalNet[width][height][5][2];
+ for(int x=0; x<width; x+=4)
+ for(int y=0; y<height; y+=4)
+ for(int p=0; p<5; p++) {
+ for(int xc=x; xc<x+4; xc++) {
+ PhysicalNet vwire = new PhysicalNet("("+xc+","+y+"-"+(y+3)+")");
+ for(int yc=y; yc<y+4; yc++)
+ sectorWires[xc][yc][p][0] = vwire;
+ }
+ for(int yc=y; yc<y+4; yc++) {
+ PhysicalNet hwire = new PhysicalNet("("+x+"-"+(x+3)+","+yc+")");
+ for(int xc=x; xc<x+4; xc++)
+ sectorWires[xc][yc][p][1] = hwire;
+ }
+ }
+
+ for(int x=4; x<width; x+=4) {
+ for(int y=0; y<height; y++) {
+ for(int p=0; p<5; p++) {
+ final int xc = x;
+ final int yc = y;
+ final int pc = p;
+ new PhysicalPip("xxx",
+ sectorWires[x-1][y][p][1],
+ new PhysicalNet[] { sectorWires[x][y][p][1] },
+ 5) {
+ public void set(boolean connected) {
+ fpslic.cell(xc-1, yc).hwire(pc).drives(fpslic.cell(xc, yc).hwire(pc), connected);
+ }
+ };
+ new PhysicalPip("xxx",
+ sectorWires[x][y][p][1],
+ new PhysicalNet[] { sectorWires[x-1][y][p][1] },
+ 5) {
+ public void set(boolean connected) {
+ fpslic.cell(xc, yc).hwire(pc).drives(fpslic.cell(xc-1, yc).hwire(pc), connected);
+ }
+ };
+ }
+ }
+ }
+
+ for(int x=0; x<width; x++) {
+ for(int y=4; y<height; y+=4) {
+ for(int p=0; p<5; p++) {
+ final int xc = x;
+ final int yc = y;
+ final int pc = p;
+ new PhysicalPip("xxx",
+ sectorWires[x][y-1][p][0],
+ new PhysicalNet[] { sectorWires[x][y][p][0] },
+ 5) {
+ public void set(boolean connected) {
+ fpslic.cell(xc, yc-1).vwire(pc).drives(fpslic.cell(xc, yc).vwire(pc), connected);
+ }
+ };
+ new PhysicalPip("xxx",
+ sectorWires[x][y][p][0],
+ new PhysicalNet[] { sectorWires[x][y-1][p][0] },
+ 5) {
+ public void set(boolean connected) {
+ fpslic.cell(xc, yc).vwire(pc).drives(fpslic.cell(xc, yc-1).vwire(pc), connected);
+ }
+ };
+ }
+ }
+ }
+
+ cells = new PhysicalFpslicCell[width][height];
+ for(int x=0; x<width; x++)
+ for(int y=0; y<height; y++) {
+ cells[x][y] = new PhysicalFpslicCell(x, y);
+ }
+ for(int x=0; x<width; x++)
+ for(int y=0; y<height; y++)
+ cells[x][y].link();
+ }
+
+ private PhysicalNet getSectorWire(int col, int row, int plane, boolean horizontal) {
+ return sectorWires[col][row][plane][horizontal ? 1 : 0];
+ }
+
+ public class PhysicalFpslicCell extends PhysicalCell {
+ private int col;
+ private int row;
+ private PhysicalNet outputNet;
+ private PhysicalNet xin;
+ private PhysicalNet yin;
+ private PhysicalNet[] local = new PhysicalNet[5];
+
+ public void place(NetList.Node n) {
+ int x = col;
+ int y = row;
+ n.x = x;
+ n.y = y;
+ n.physicalCell = this;
+ Fpslic.Cell cell = fpslic.cell(x,y);
+ cell.c(XLUT);
+ cell.b(false);
+ cell.f(false);
+ cell.xi(NW);
+ cell.yi(EAST);
+ String type = n.getType();
+ if (type.equals("and2")) cell.xlut(LUT_SELF & LUT_OTHER);
+ else if (type.equals("or2")) cell.xlut(LUT_SELF | LUT_OTHER);
+ else if (type.equals("xor2")) cell.xlut(LUT_SELF ^ LUT_OTHER);
+ else if (type.equals("buf")) cell.xlut(LUT_SELF);
+ else if (type.equals("inv")) cell.xlut(~LUT_SELF);
+ else if (type.equals("cell0")) return;
+ }
+
+ private Fpslic.Cell cell() { return fpslic.cell(col, row); }
+ public PhysicalNet getNet(String name) {
+ if (name.equals("out")) return outputNet;
+ if (name.equals("xi")) return xin;
+ if (name.equals("yi")) return yin;
+ throw new RuntimeException("unknown");
+ }
+
+ public void setFunction(String type) {
+ Fpslic.Cell cell = cell();
+ cell.c(XLUT);
+ cell.xo(false);
+ cell.b(false);
+ cell.f(false);
+ if (type.equals("and2")) cell.xlut(LUT_SELF & LUT_OTHER);
+ else if (type.equals("or2")) cell.xlut(LUT_SELF | LUT_OTHER);
+ else if (type.equals("xor2")) cell.xlut(LUT_SELF ^ LUT_OTHER);
+ else if (type.equals("buf")) cell.xlut(LUT_SELF);
+ else if (type.equals("inv")) cell.xlut(~LUT_SELF);
+ }
+
+ public void link() {
+ // FIXME wow, this is a horrendous hack!
+ if (getCell(col-1, row+1) != null)
+ new PhysicalPip(this+".xiNW", getCell(col-1, row+1).getNet("out"), new PhysicalNet[] { xin }, 5) {
+ public void set(boolean connected) { cell().xi(connected ? NW : NONE); }
+ };
+ if (getCell(col-1, row-1) != null)
+ new PhysicalPip(this+".xiSW", getCell(col-1, row-1).getNet("out"), new PhysicalNet[] { xin }, 5) {
+ public void set(boolean connected) { cell().xi(connected ? SW : NONE); }
+ };
+ if (getCell(col+1, row+1) != null)
+ new PhysicalPip(this+".xiNE", getCell(col+1, row+1).getNet("out"), new PhysicalNet[] { xin }, 5) {
+ public void set(boolean connected) { cell().xi(connected ? NE : NONE); }
+ };
+ if (getCell(col+1, row-1) != null)
+ new PhysicalPip(this+".xiSE", getCell(col+1, row-1).getNet("out"), new PhysicalNet[] { xin }, 5) {
+ public void set(boolean connected) { cell().xi(connected ? SE : NONE); }
+ };
+ }
+
+ private PhysicalFpslicCell(int col, int row) {
+ this.row = row;
+ this.col = col;
+ outputNet = new PhysicalNet(this.toString()+".out");
+ xin = new PhysicalNet(this.toString()+".xi");
+ yin = new PhysicalNet(this.toString()+".yi");
+ for(int j=0; j<5; j++) {
+
+ // plane 3 is reserved for debugging
+ if (j==3) continue;
+
+ final int i = j;
+ local[i] = new PhysicalNet(this.toString()+".L"+i);
+ new PhysicalPip(this+".h"+i, null, new PhysicalNet[] { local[i], getSectorWire(col, row, i, true) }) {
+ public void set(boolean connected) { cell().h(i, connected); }
+ };
+ new PhysicalPip(this+".v"+i, null, new PhysicalNet[] { local[i], getSectorWire(col, row, i, false) }) {
+ public void set(boolean connected) { cell().v(i, connected); }
+ };
+ new PhysicalPip(this+".xi"+i, local[i], new PhysicalNet[] { xin }) {
+ public void set(boolean connected) { cell().xi(connected ? i : NONE); }
+ };
+ new PhysicalPip(this+".yi"+i, local[i], new PhysicalNet[] { yin }) {
+ public void set(boolean connected) { cell().yi(connected ? i : NONE); }
+ };
+ new PhysicalPip(this+".o"+i, outputNet, new PhysicalNet[] { local[i] }) {
+ public void set(boolean connected) { cell().out(i, connected); }
+ };
+ }
+ }
+ public String toString() { return "cell@("+col+","+row+")"; }
+ }
+
+}
\ No newline at end of file