LichenDataImpl1.Mesa
Last tweaked by Mike Spreitzer on February 28, 1988 6:38:14 pm PST
DIRECTORY AbSets, AMBridge, Basics, BasicTime, BiRels, Convert, Interpreter, InterpreterOps, IntStuff, IO, LichenDataOps, LichenDataStructure, LichenIntBasics, List, ProcessProps, Rope, RopeHash, SetBasics, SymTab;
LichenDataImpl1:
CEDAR
PROGRAM
IMPORTS AbSets, AMBridge, Basics, BiRels, Convert, InterpreterOps, IntStuff, IO, LichenDataOps, LichenDataStructure, List, ProcessProps, Rope, RopeHash, SetBasics, SymTab
EXPORTS LichenDataStructure
=
BEGIN OPEN IB:LichenIntBasics, IB, LichenDataStructure, LichenDataOps, Sets:AbSets;
nyet: PUBLIC ERROR ~ CODE;
Warning: PUBLIC SIGNAL [msg: ROPE, v1, v2, v3, v4, v5: REF ANY ← NIL] ~ CODE;
Error: PUBLIC ERROR [msg: ROPE, v1, v2, v3, v4, v5: REF ANY ← NIL] ~ CODE;
PIndex:
PUBLIC
PROC [d: Design, ep: Port, parent: Port ←
NIL]
RETURNS [
LNAT] ~ {
IF parent=NIL THEN parent ← d.PParent[ep];
{children: Seq--of child-- ~ BiRels.DeRef[d.sub.ApplyA[parent].MA];
RETURN [children.Lookup[AV[ep]].MI]}};
WIndex:
PUBLIC
PROC [d: Design, ew: Wire, parent: Wire ←
NIL]
RETURNS [
LNAT] ~ {
IF parent=NIL THEN parent ← d.WParent[ew];
{children: Seq--of child-- ~ BiRels.DeRef[d.sub.ApplyA[parent].MA];
RETURN [children.Lookup[AV[ew]].MI]}};
PIsAncestor:
PUBLIC
PROC [d: Design, ancestor, descendant: Port]
RETURNS [
BOOL] ~ {
IF ancestor=NIL OR descendant=NIL THEN ERROR;
DO
IF descendant=ancestor THEN RETURN [TRUE];
IF descendant=NIL THEN RETURN [FALSE];
descendant ← d.PParent[descendant];
d ← d; ENDLOOP};
WIsAncestor:
PUBLIC
PROC [d: Design, ancestor, descendant: Wire]
RETURNS [
BOOL] ~ {
IF ancestor=NIL OR descendant=NIL THEN ERROR;
DO
IF descendant=ancestor THEN RETURN [TRUE];
IF descendant=NIL THEN RETURN [FALSE];
descendant ← d.WParent[descendant];
d ← d; ENDLOOP};
ConndWire:
PUBLIC
PROC [c: Cell, p: Port]
RETURNS [Wire] ~ {
WITH c
SELECT
FROM
ct: CellType => {
IF NOT ct.simpleRep THEN ERROR;
RETURN [NARROW[ct.exports.ApplyA[p].MDA]]};
ci: CellInstance => RETURN [NARROW[ci.conns.ApplyA[p].MDA]];
ENDCASE => ERROR;
};
ACtName:
PUBLIC
PROC [design: Design, ct: CellType]
RETURNS [
ROPE] ~ {
RETURN [NARROW[design.ctName.Lookup[goal: AV[ct], side: left].MDA]]};
BestPName:
PUBLIC
PROC [ct: CellType, p: Port]
RETURNS [SteppyName] ~ {
RETURN [VSn[ct.fullName[p].Lookup[goal: AV[p], side: left].Val]]};
BestWName:
PUBLIC
PROC [ct: CellType, w: Wire]
RETURNS [SteppyName] ~ {
RETURN [VSn[ct.fullName[w].Lookup[goal: AV[w], side: left].Val]]};
BestIName:
PUBLIC
PROC [ct: CellType, ci: CellInstance]
RETURNS [SteppyName] ~ {
RETURN [VSn[ct.fullName[i].Lookup[goal: AV[ci], side: left].Val]]};
DimName: ARRAY Dim2 OF ROPE = [X: "X", Y: "Y"];
Describe:
PUBLIC
PROC [design: Design, subject:
REF
ANY, relativeTo:
REF
ANY ←
NIL, nameGen: NameGenerator ←
NIL]
RETURNS [name:
ROPE] = {
name ← UnparseSteppyName[SteppyDescribe[design, subject, relativeTo, nameGen]];
RETURN};
SteppyDescribe:
PUBLIC
PROC [design: Design, subject:
REF
ANY, relativeTo:
REF
ANY ←
NIL, nameGen: NameGenerator ←
NIL]
RETURNS [name: SteppyName] = {
IF nameGen = NIL THEN nameGen ← defaultNameGen;
IF subject = relativeTo
THEN name ← noName
ELSE
WITH subject
SELECT
FROM
d: Design => {
short: ROPE ← NARROW[d.names.AnElt[].MDA];
IF short=
NIL
THEN {
short ← nameGen.GenerateName[nameGen.data, subject];
IF NOT d.names.AddA[short] THEN ERROR};
name ← OSn[short];
RETURN};
ct: CellType => {
short: ROPE ← ACtName[design, ct];
IF short=
NIL
THEN {
short ← nameGen.GenerateName[nameGen.data, subject];
design.ctName.AddNewAA[ct, short]};
name ← OSn[short];
IF NOT design.cellTypes.HasMemA[ct] THEN ERROR;
name ← SNCat[SteppyDescribe[design, design, relativeTo, nameGen], name];
RETURN};
v: Vertex => {
cct: CellType ~ design.VCct[v];
WITH relativeTo
SELECT
FROM
aw: Wire => {w: Wire ~
NARROW[v];
IF NOT WIsAncestor[design, aw, w] THEN ERROR;
{msn: MaybeSteppyName ~ ScanRelativeNames[design, cct, w, aw, w, AcceptAnySteppyName];
IF NOT msn.found THEN ERROR;
name ← msn.it;
RETURN}};
ENDCASE => NULL;
{mv: Sets.MaybeValue ~ cct.fullName[v.class].Lookup[goal: AV[v], side: left];
IF mv.found THEN name ← VSn[mv.it] ELSE KnowVertexName[design, v, name ← OSn[nameGen.GenerateName[nameGen.data, subject]]];
IF relativeTo#cct THEN name ← SNCat[SteppyDescribe[design, cct, relativeTo, nameGen], name];
RETURN}};
port: Port => {
cct: CellType ~ design.PCct[port];
WITH relativeTo
SELECT
FROM
ap: Port => {
IF NOT PIsAncestor[design, ap, port] THEN ERROR;
{msn: MaybeSteppyName ~ ScanRelativeNames[design, cct, p, ap, port, AcceptAnySteppyName];
IF NOT msn.found THEN ERROR;
name ← msn.it;
RETURN}};
ENDCASE => NULL;
{mv: Sets.MaybeValue ~ cct.fullName[p].Lookup[goal: AV[port], side: left];
IF mv.found THEN name ← VSn[mv.it] ELSE KnowPortName[design, port, name ← OSn[nameGen.GenerateName[nameGen.data, subject]]];
IF relativeTo#cct THEN name ← SNCat[SteppyDescribe[design, cct, relativeTo, nameGen], name];
RETURN}};
ENDCASE => ERROR;
};
genBland: NameGenerator =
NEW [NameGeneratorPrivate ← [
GenerateBlandName,
NEW [NameCountsPrivate ← []]
]];
NameCounts: TYPE = REF NameCountsPrivate;
NameCountsPrivate:
TYPE =
RECORD [
design, cellType, port, vertex: INT ← 0
];
GenerateBlandName:
PROC [data, subject:
REF
ANY]
RETURNS [name:
ROPE] = {
nc: NameCounts = NARROW[data];
name ← GenByCount[nc, "#", subject];
};
GenByCount:
PROC [nc: NameCounts, sep:
ROPE, subject:
REF
ANY]
RETURNS [name:
ROPE] = {
n: INT ← 0;
WITH subject
SELECT
FROM
d: Design => {n ← nc.design ← nc.design + 1; name ← "D"};
ct: CellType => {n ← nc.cellType ← nc.cellType + 1; name ← "CT"};
p: Port => {n ← nc.port ← nc.port + 1; name ← "P"};
v: Vertex => {n ← nc.vertex ← nc.vertex + 1; name ← "V"};
ENDCASE => ERROR;
name ← name.Cat[sep, Convert.RopeFromInt[n]];
};
genSymbol: NameGenerator =
NEW [NameGeneratorPrivate ← [
GenerateSymbolName,
NEW [TVNameGeneratorPrivate ← [
nc: NEW [NameCountsPrivate ← []],
symbols: LIST[SymTab.Create[]]
]]
]];
TVNameGenerator: TYPE = REF TVNameGeneratorPrivate;
TVNameGeneratorPrivate:
TYPE =
RECORD [
nc: NameCounts,
symbols: Interpreter.SymbolsList
];
GenerateSymbolName:
PROC [data, subject:
REF
ANY]
RETURNS [name:
ROPE] = {
tvng: TVNameGenerator ~ NARROW[data];
evalHead: InterpreterOps.EvalHead ~ NARROW[List.Assoc[$EvalHead, ProcessProps.GetPropList[]]];
syms: Interpreter.SymbolsList ~ IF evalHead#NIL AND evalHead.specials#NIL THEN evalHead.specials ELSE tvng.symbols;
name ← Rope.Concat[IF syms=tvng.symbols THEN "&&" ELSE "&", GenByCount[tvng.nc, "", subject]];
TRUSTED {InterpreterOps.RegisterTV[
name: name,
tv: AMBridge.TVForReferent[
WITH subject
SELECT
FROM
d: Design => NEW [Design ← d],
ct: CellType => NEW [CellType ← ct],
p: Port => NEW [Port ← p],
v: Vertex => NEW [Vertex ← v],
ENDCASE => ERROR],
symbolsList: syms]};
RETURN};
defaultNameGen: NameGenerator ~ genSymbol;
ScanRelativeNames:
PUBLIC
PROC [d: Design, ct: CellType, class: PWClass, anc, des:
REF
ANY,
Test:
PROC [SteppyName]
RETURNS [
BOOL]]
RETURNS [msn: MaybeSteppyName ← [
FALSE, noName]] ~ {
countA: LNAT ~ ct.fullName[class].MappingSize[AV[anc]].EN;
countD: LNAT ~ ct.fullName[class].MappingSize[AV[des]].EN;
OuterA:
PROC [va: Sets.Value]
RETURNS [
BOOL] ~ {
na: SteppyName ~ VSn[va];
InnerD:
PROC [vd: Sets.Value]
RETURNS [
BOOL] ~ {
nd: SteppyName ~ VSn[vd];
RETURN [(msn ← SteppyIsPrefix[na, nd]).found]};
RETURN [ct.fullName[class].ScanMapping[AV[des], InnerD].found]};
OuterD:
PROC [vd: Sets.Value]
RETURNS [
BOOL] ~ {
nd: SteppyName ~ VSn[vd];
InnerA:
PROC [va: Sets.Value]
RETURNS [
BOOL] ~ {
na: SteppyName ~ VSn[va];
RETURN [(msn ← SteppyIsPrefix[na, nd]).found]};
RETURN [ct.fullName[class].ScanMapping[AV[anc], InnerA].found]};
IF countA < countD
THEN [] ← ct.fullName[class].ScanMapping[AV[anc], OuterA]
ELSE [] ← ct.fullName[class].ScanMapping[AV[des], OuterD];
RETURN};
AcceptAnySteppyName: PUBLIC PROC [SteppyName] RETURNS [BOOL] ~ {RETURN [TRUE]};
LSn:
PUBLIC
PROC [l: NameStepList]
RETURNS [SteppyName]
~ {RETURN [[l, Grade[l]]]};
Grade:
PROC [steps: NameStepList]
RETURNS [grade: SteppyNameGrade ← [
FALSE, 0,
FALSE, 0]] ~ {
last: ROPE ← NIL;
FOR steps ← steps, steps.rest
WHILE steps#
NIL
DO
WITH steps.first
SELECT
FROM
x: ROPE => {grade.nonsubs ← grade.nonsubs+1; last ← x};
x: REF INT => grade.subs ← grade.subs+1;
ENDCASE => ERROR;
ENDLOOP;
IF last#NIL THEN [grade.global, grade.gend] ← Analast[last];
RETURN};
Analast:
PROC [last:
ROPE]
RETURNS [global, gend:
BOOL ←
FALSE] ~ {
xLen: INT ~ last.Length;
IF
NOT (global ← last.InlineFetch[xLen-1]='!)
THEN {
FOR i:
INT
DECREASING
IN [0 .. xLen)
DO
SELECT last.InlineFetch[i]
FROM
'#, '& => {gend ← TRUE; EXIT};
ENDCASE => NULL;
ENDLOOP;
};
RETURN};
ParseSteppyName:
PUBLIC
PROC [raw:
ROPE]
RETURNS [SteppyName] ~ {
len: INT ~ raw.Length;
steps: TList ← [];
i: INT ← 0;
DO
start: INT ~ i;
type: {unk, num, name} ← unk;
WHILE i<len
DO
SELECT raw.InlineFetch[i]
FROM
'/ => EXIT;
IN ['0 .. '9] => IF type=unk THEN type ← num;
ENDCASE => type ← name;
i ← i + 1;
ENDLOOP;
{part: ROPE ~ raw.Substr[start: start, len: i-start];
SELECT type
FROM
unk, name => steps ← steps.Append[part];
num => steps ← steps.Append[NewInt[Convert.IntFromRope[part]]];
ENDCASE => ERROR;
IF i=len THEN EXIT ELSE i ← i + 1;
}ENDLOOP;
RETURN LSn[steps.head]};
UnparseSteppyName:
PUBLIC
PROC [s: SteppyName]
RETURNS [u:
ROPE] ~ {
u ← NIL;
FOR steps: NameStepList ← s.steps, steps.rest
WHILE steps#
NIL
DO
r:
ROPE ~
WITH steps.first
SELECT
FROM
x: ROPE => x,
x: REF INT => Convert.RopeFromInt[x^],
ENDCASE => ERROR;
IF u#NIL THEN u ← u.Cat["/", r] ELSE u ← u.Concat[r];
ENDLOOP;
RETURN};
ActualName:
PROC [instanceName, portName: SteppyName]
RETURNS [actualName: SteppyName] ~ {
IF portName.grade.global THEN RETURN [portName];
actualName ← SNCat[instanceName, portName];
RETURN};
SNCat:
PUBLIC
PROC [a, b: SteppyName]
RETURNS [SteppyName] ~ {
IF b=noName THEN RETURN [a];
IF a=noName THEN RETURN [b];
IF b.grade.nonsubs>0
THEN
RETURN [[
steps: List.Append[a.steps, b.steps],
grade: [
global: b.grade.global,
nonsubs: a.grade.nonsubs + b.grade.nonsubs,
gend: b.grade.gend,
subs: a.grade.subs + b.grade.subs]
]];
RETURN [[
steps: List.Append[a.steps, b.steps],
grade: [
global: a.grade.global,
nonsubs: a.grade.nonsubs,
gend: a.grade.gend,
subs: a.grade.subs + b.grade.subs]
]]};
SNPrepend:
PUBLIC
PROC [ns: NameStep, sn: SteppyName]
RETURNS [SteppyName] ~ {
ans: SteppyName ← [steps: CONS[ns, sn.steps], grade: sn.grade];
WITH ns
SELECT
FROM
x: ROPE => IF (ans.grade.nonsubs ← ans.grade.nonsubs+1) = 1 THEN [ans.grade.global, ans.grade.gend] ← Analast[x];
x: REF INT => ans.grade.subs ← ans.grade.subs+1;
ENDCASE => ERROR;
RETURN [ans]};
SNAppend:
PUBLIC
PROC [sn: SteppyName, ns: NameStep]
RETURNS [SteppyName] ~ {
ans: SteppyName ← [steps: List.Append[sn.steps, LIST[ns]], grade: sn.grade];
WITH ns
SELECT
FROM
x:
ROPE => {
ans.grade.nonsubs ← ans.grade.nonsubs+1;
[ans.grade.global, ans.grade.gend] ← Analast[x]};
x: REF INT => ans.grade.subs ← ans.grade.subs+1;
ENDCASE => ERROR;
RETURN [ans]};
SteppyIsPrefix:
PUBLIC
PROC [prefix, full: SteppyName]
RETURNS [MaybeSteppyName] ~ {
IF prefix.grade.nonsubs>full.grade.nonsubs OR prefix.grade.subs>full.grade.subs THEN RETURN [[FALSE, noName]];
{tail: NameStepList ~ List.NthTail[full.steps, prefix.grade.nonsubs+prefix.grade.subs];
IF NameStepListEqual[prefix.steps, full.steps, NIL, tail] THEN RETURN [[FALSE, noName]];
{suffix: SteppyName ~ LSn[tail];
ok:
BOOL ~
IF suffix.grade.nonsubs>0
THEN full.grade.global=suffix.grade.global AND full.grade.nonsubs=prefix.grade.nonsubs+suffix.grade.nonsubs AND full.grade.gend=suffix.grade.gend AND full.grade.subs=prefix.grade.subs+suffix.grade.subs
ELSE full.grade.global=prefix.grade.global AND full.grade.nonsubs=prefix.grade.nonsubs AND full.grade.gend=prefix.grade.gend AND full.grade.subs=prefix.grade.subs+suffix.grade.subs;
IF ok THEN RETURN [[TRUE, suffix]] ELSE RETURN [[FALSE, noName]]}}};
SteppyNameGradeCompare:
PUBLIC
PROC [g1, g2: SteppyNameGrade]
RETURNS [Basics.Comparison] ~ {
IF g1 = g2 THEN RETURN [equal];
RETURN [
SELECT
TRUE
FROM
g1.global<g2.global => greater,
g1.global>g2.global => less,
g1.gend<g2.gend => less,
g1.gend>g2.gend => greater,
g1.nonsubs<g2.nonsubs => less,
g1.nonsubs>g2.nonsubs => greater,
g1.subs<g2.subs => less,
g1.subs>g2.subs => greater,
ENDCASE => ERROR--they were equal!--];
};
NameStepListCompare:
PUBLIC
PROC [l1, l2: NameStepList]
RETURNS [c: Basics.Comparison] ~ {
WHILE l1#l2
DO
WITH l1.first
SELECT
FROM
x1:
REF
INT =>
WITH l2.first
SELECT
FROM
x2: REF INT => IF (c ← Basics.CompareInt[x1^, x2^]) # equal THEN RETURN;
x2: ROPE => RETURN [greater];
ENDCASE => ERROR;
x1:
ROPE =>
WITH l2.first
SELECT
FROM
x2: ROPE => IF (c ← x1.Compare[x2]) # equal THEN RETURN;
x2: REF INT => RETURN [less];
ENDCASE => ERROR;
ENDCASE => ERROR;
l1 ← l1.rest;
l2 ← l2.rest;
ENDLOOP;
RETURN [equal]};
NameStepListEqual:
PUBLIC
PROC [l1, l2: NameStepList, clip1, clip2: NameStepList ←
NIL]
RETURNS [
BOOL] ~ {
WHILE l1#clip1
AND l2#clip2
DO
WITH l1.first
SELECT
FROM
x:
ROPE =>
WITH l2.first
SELECT
FROM
y: ROPE => IF NOT x.Equal[y] THEN RETURN [FALSE];
y: REF INT => RETURN [FALSE];
ENDCASE => ERROR;
x:
REF
INT =>
WITH l2.first
SELECT
FROM
y: ROPE => RETURN [FALSE];
y: REF INT => IF x^#y^ THEN RETURN [FALSE];
ENDCASE => ERROR;
ENDCASE => ERROR;
l1 ← l1.rest;
l2 ← l2.rest;
ENDLOOP;
RETURN [(l1=clip1) = (l2=clip2)]};
nameStepSpace:
PUBLIC SetBasics.Space ←
NEW [SetBasics.SpacePrivate ← [
Contains: StepContains,
Equal: StepEqual,
Hash: StepHash,
Compare: StepCompare,
Print: StepPrint,
name: "name steps"
]];
StepContains:
PROC [data:
REF
ANY, v: Sets.Value]
RETURNS [
BOOL] ~ {
RETURN [
WITH v.ra
SELECT
FROM
y: ROPE => TRUE,
y: REF INT => TRUE,
ENDCASE => FALSE]};
StepEqual:
PROC [data:
REF
ANY, v1, v2: Sets.Value]
RETURNS [
BOOL] ~ {
WITH v1.
VA
SELECT
FROM
x:
REF
INT =>
WITH v2.
VA
SELECT
FROM
y: REF INT => RETURN [x^ = y^];
y: ROPE => RETURN [FALSE];
ENDCASE => ERROR;
x:
ROPE =>
WITH v2.
VA
SELECT
FROM
y: REF INT => RETURN [FALSE];
y: ROPE => RETURN [x.Equal[y]];
ENDCASE => ERROR;
ENDCASE => ERROR;
};
StepHash:
PROC [data:
REF
ANY, v: Sets.Value]
RETURNS [
CARDINAL] ~ {
WITH v.
VA
SELECT
FROM
x: REF INT => RETURN SetBasics.HashIntI[x^];
x: ROPE => RETURN [RopeHash.FromRope[rope: x]];
ENDCASE => ERROR;
};
StepCompare:
PROC [data:
REF
ANY, v1, v2: Sets.Value]
RETURNS [Basics.Comparison] ~ {
WITH v1.
VA
SELECT
FROM
x:
REF
INT =>
WITH v2.
VA
SELECT
FROM
y: REF INT => RETURN [SetBasics.CompareIntI[x^, y^]];
y: ROPE => RETURN [less];
ENDCASE => ERROR;
x:
ROPE =>
WITH v2.
VA
SELECT
FROM
y: REF INT => RETURN [greater];
y: ROPE => RETURN [x.Compare[y]];
ENDCASE => ERROR;
ENDCASE => ERROR;
};
StepPrint:
PROC [data:
REF
ANY, v: Sets.Value, to:
IO.
STREAM, depth, length:
INT, verbose:
BOOL] ~ {
WITH v.
VA
SELECT
FROM
x: ROPE => to.PutRope[x];
x: REF INT => to.Put[[integer[x^]]];
ENDCASE => ERROR;
RETURN};
steppyNameSpace:
PUBLIC SetBasics.Space ←
NEW [SetBasics.SpacePrivate ← [
Contains: SteppyNamesContains,
Equal: SteppyNamesEqual,
Hash: SteppyNamesHash,
Compare: SteppyNamesCompare,
Print: SteppyNamesPrint,
name: "steppy names"
]];
SteppyNamesContains:
PROC [data:
REF
ANY, v: Sets.Value]
RETURNS [
BOOL] ~ {
RETURN [
WITH v.ra
SELECT
FROM
x: NameStepList => TRUE,
ENDCASE => FALSE]};
SteppyNamesEqual:
PROC [data:
REF
ANY, v1, v2: Sets.Value]
RETURNS [
BOOL] ~ {
RETURN [SteppyNamesCompare[data, v1, v2]=equal]};
SteppyNamesHash:
PROC [data:
REF
ANY, v: Sets.Value]
RETURNS [hash:
CARDINAL ← 0] ~ {
n: SteppyName ← VSn[v];
FOR steps: NameStepList ← n.steps, steps.rest
WHILE steps#
NIL
DO
hash ← hash + (
WITH steps.first
SELECT
FROM
x: ROPE => RopeHash.FromRope[x],
x: REF INT => SetBasics.HashIntI[x^],
ENDCASE => ERROR);
ENDLOOP;
RETURN};
SteppyNamesCompare:
PROC [data:
REF
ANY, v1, v2: Sets.Value]
RETURNS [c: Basics.Comparison] ~ {
n1: SteppyName ~ VSn[v1];
n2: SteppyName ~ VSn[v2];
IF (c ← SteppyNameGradeCompare[n1.grade, n2.grade])#equal THEN RETURN;
c ← NameStepListCompare[n1.steps, n2.steps];
RETURN};
SteppyNamesPrint:
PROC [data:
REF
ANY, v: Sets.Value, to:
IO.
STREAM, depth, length:
INT, verbose:
BOOL] ~ {
name: SteppyName ~ VSn[v];
to.PutRope[UnparseSteppyName[name]];
RETURN};
emptyRopeSet: PUBLIC Set ← Sets.CreateEmptySet[SetBasics.ropes[TRUE]];
emptySteppySet: PUBLIC Set ← Sets.CreateEmptySet[steppyNameSpace];
endOfQ: PUBLIC Vertex ~ NEW [VertexPrivate[i]];
CopyTil:
PUBLIC
PROC [old: TList]
RETURNS [new: TList ← []] ~ {
FOR cur:
LORA ← old.head, cur.rest
WHILE cur#old.tail
DO
this: LORA ~ LIST[cur.first];
IF new.tail=NIL THEN new.head ← this ELSE new.tail.rest ← this;
new.tail ← this;
ENDLOOP;
RETURN};
NewInt:
PUBLIC
PROC [i:
INT]
RETURNS [
REF
INT] ~ {
IF i IN [0 .. 64] THEN RETURN [intRefs[i]];
RETURN [NEW [INT ← i]]};
IntRefArray: TYPE ~ ARRAY [0 .. 64] OF REF INT;
intRefs: REF IntRefArray ~ NEW [IntRefArray ← ALL[NIL]];
Start:
PROC ~ {
FOR i: INT IN [0 .. 64] DO intRefs[i] ← NEW [INT ← i] ENDLOOP;
RETURN};
Start[];
END.