[_CD6_]<autolayout>Phoenix23>CCGImpl.mesa!1

-- File: CCGImpl.mesa

-- Last Edited by: CSChow, January 17, 1985 10:57:00 pm PST

-- Note: CCG = ChannelConstraintGraph

DIRECTORY

CCG;

CCGImpl: CEDAR PROGRAM

EXPORTS CCG = BEGIN OPEN CCG;

Ref: TYPE = REF Rep;

Rep: PUBLIC TYPE = RECORD[size: NAT ← 0, vertices: ARRAY NodeIndex OF ChNode];

ChNode: TYPE = RECORD[

ch: REF ← NIL,

negEdges, posEdges: Edges ← NIL,

negPosition: INT ← LAST[INT], posPosition: INT ← FIRST[INT],

negInCount, posInCount: NAT ← 0];

Edges: TYPE = REF EdgesRep;

EdgesRep: TYPE = RECORD[size: NAT ← 0, edgeArray: ARRAY EdgeIndex OF Edge];

Edge: TYPE = RECORD[node: NodeIndex, wt: INT];

EdgeIndex: TYPE = [1..MaxEdges];

InvalidNode: PUBLIC ERROR = CODE;

FindRootError: PUBLIC ERROR[reason: Reasons1] = CODE;

AssignNodeError: PUBLIC ERROR[reason: Reasons2] = CODE;

Create: PUBLIC PROC[] RETURNS[Ref] =

{RETURN[NEW[Rep]]}; -- Create --

CreateNode: PUBLIC PROC[grph: Ref, ch: REF ← NIL] RETURNS[NodeIndex] = {

grph.size ← grph.size + 1;

grph.vertices[grph.size] ← ChNode[ch: ch, negEdges: NEW[EdgesRep], posEdges: NEW[EdgesRep]];

RETURN[grph.size]

}; -- CreateNode --

DestroyNode: PUBLIC PROC[grph: Ref, node: NodeIndex, p: CleanUpChsProc] = {

size: NodeIndex = grph.size;

IF node > size THEN ERROR InvalidNode;

p[grph.vertices[node].ch, grph.vertices[size].ch];

grph.vertices[node] ← grph.vertices[size];

grph.vertices[size] ← ChNode[];

grph.size ← size - 1;

}; -- DestroyNode --

Size: PUBLIC PROC [grph: Ref] RETURNS [NAT] ={RETURN [grph.size]}; --Size--

ConstrainNodes: PUBLIC PROC[grph: Ref, negNd, posNd: NodeIndex, wt: INT] = {

posEdges: Edges ← grph.vertices[negNd].posEdges;

pDone: BOOL ← FALSE;

negEdges: Edges ← grph.vertices[posNd].negEdges;

nDone: BOOL ← FALSE;

-- Update positive Edges --

FOR i: EdgeIndex IN [1..posEdges.size] DO

IF posEdges.edgeArray[i].node = posNd THEN {

posEdges.edgeArray[i].wt ← MAX[wt, posEdges.edgeArray[i].wt];

pDone ← TRUE;

EXIT}

ENDLOOP;

IF NOT pDone THEN {

posEdges.size ← posEdges.size + 1;

posEdges.edgeArray[posEdges.size] ← Edge[posNd, wt];

grph.vertices[posNd].posInCount ← grph.vertices[posNd].posInCount.SUCC};

-- Updatge negative Edges --

FOR i: EdgeIndex IN [1..negEdges.size] DO

IF negEdges.edgeArray[i].node = negNd THEN {

negEdges.edgeArray[i].wt ← MAX[wt, negEdges.edgeArray[i].wt];

nDone ← TRUE;

EXIT}

ENDLOOP;

IF NOT nDone THEN {

negEdges.size ← negEdges.size +1;

negEdges.edgeArray[negEdges.size] ← Edge[negNd, wt];

grph.vertices[negNd].negInCount ← grph.vertices[negNd].negInCount.SUCC};

}; --ConstrainNodes--

CyclicConstrainp: PUBLIC PROC [grph: Ref, negNd, posNd: NodeIndex] RETURNS [cyclic: BOOL] ={

posNdNbrs: ARRAY NodeIndex OF NodeIndex;

nbrsCount: NAT ← 0;

findNbrs: PROC RETURNS [BOOL] ={

nd: NodeIndex;

IF nbrsCount = 0

THEN {cyclic ← FALSE; RETURN[TRUE]}

ELSE {nd ← posNdNbrs[nbrsCount]; nbrsCount ← nbrsCount.PRED};

FOR nbrNo: NAT ← grph.vertices[nd].posEdges.size, nbrNo.PRED UNTIL nbrNo = 0 DO

ndNbr: NodeIndex ← grph.vertices[nd].posEdges.edgeArray[nbrNo].node;

IF ndNbr = negNd

THEN {cyclic ← TRUE; RETURN[TRUE]}

ELSE {posNdNbrs[(nbrsCount ← nbrsCount.SUCC)] ← ndNbr}

ENDLOOP;

RETURN [FALSE];

}; --findNbrs--

posNdNbrs[(nbrsCount ← nbrsCount.SUCC)] ← posNd;

THROUGH [0..grph.size * MaxEdges) DO

IF findNbrs[] THEN RETURN

ENDLOOP;

ERROR; --Implies that there is already a loop in the constraint graph--

}; --CyclicConstrainp--

ResetNode: PUBLIC PROC[grph: Ref, nd: NodeIndex] = {

ch: REF ← grph.vertices[nd].ch;

posEdges: Edges ← grph.vertices[nd].posEdges;

negEdges: Edges ← grph.vertices[nd].negEdges;

posEdges.size ← 0;

negEdges.size ← 0;

grph.vertices[nd] ← ChNode[ch: ch, negEdges: negEdges, posEdges: posEdges];

}; --ResetNode--

ResetAllNodes: PUBLIC PROC[grph: Ref] ={

FOR nd: NodeIndex IN [1..grph.size] DO

ResetNode[grph, nd]

ENDLOOP;

}; --ResetAllNodes--

PosAssignNodePosition: PUBLIC PROC[grph: Ref, root: NodeIndex] ={

nodes: ARRAY NodeIndex OF NodeIndex;

indexHd, indexTl: NAT ← 0;

IF grph.vertices[root].posInCount # 0 THEN ERROR AssignNodeError[NotARoot];

nodes[indexTl ← indexTl + 1] ← root;

THROUGH [0..grph.size) DO {

n0: NodeIndex ← nodes[indexHd ← indexHd +1];

edges: Edges;

nodePstn: INT;

IF indexHd > indexTl THEN ERROR AssignNodeError[CyclicGraph];

edges ← grph.vertices[n0].posEdges;

nodePstn ← grph.vertices[n0].posPosition;

FOR i: EdgeIndex IN [1..edges.size] DO{

nbdNode: NodeIndex ← edges.edgeArray[i].node;

newPstn: INT ← nodePstn + edges.edgeArray[i].wt;

oldPstn: INT ← grph.vertices[nbdNode].posPosition;

IF newPstn > oldPstn THEN grph.vertices[nbdNode].posPosition ← newPstn;

IF (grph.vertices[nbdNode].posInCount ← grph.vertices[nbdNode].posInCount - 1) = 0 THEN {nodes[indexTl ← indexTl +1] ← nbdNode};

} ENDLOOP;

grph.vertices[n0].posEdges.size ← 0; -- Remove all the edges --

}

ENDLOOP;

}; -- PosAssignNodePosition--

NegAssignNodePosition: PUBLIC PROC[grph: Ref, root: NodeIndex] ={

nodes: ARRAY NodeIndex OF NodeIndex;

indexHd, indexTl: NAT ← 0;

IF grph.vertices[root].negInCount # 0 THEN ERROR AssignNodeError[CyclicGraph];

nodes[indexTl ← indexTl + 1] ← root;

THROUGH [0..grph.size) DO {

n0: NodeIndex ← nodes[indexHd ← indexHd +1];

edges: Edges;

nodePstn: INT;

IF indexHd > indexTl THEN ERROR AssignNodeError[CyclicGraph];

edges ← grph.vertices[n0].negEdges;

nodePstn ← grph.vertices[n0].negPosition;

FOR i: EdgeIndex IN [1..edges.size] DO{

nbdNode: NodeIndex ← edges.edgeArray[i].node;

newPstn: INT ← nodePstn - edges.edgeArray[i].wt;

oldPstn: INT ← grph.vertices[nbdNode].negPosition;

IF newPstn < oldPstn THEN grph.vertices[nbdNode].negPosition ← newPstn;

IF (grph.vertices[nbdNode].negInCount ← grph.vertices[nbdNode].negInCount - 1) = 0 THEN {nodes[indexTl ← indexTl +1] ← nbdNode};

} ENDLOOP;

grph.vertices[n0].negEdges.size ← 0; -- Remove all the edges --

}

ENDLOOP;

}; -- NegAssignNodePosition--

NodePosition: PUBLIC PROC[grph: Ref, nd: NodeIndex, which: GraphDirection] RETURNS[INT] = {

SELECT which FROM

pos => RETURN[grph.vertices[nd].posPosition];

neg => RETURN[grph.vertices[nd].negPosition];

ENDCASE => ERROR;

}; --NodePosition--

SetNodePosition: PUBLIC PROC[grph: Ref, nd: NodeIndex, which: GraphDirection, position: INT] = {

SELECT which FROM

pos => grph.vertices[nd].posPosition ← position;

neg => grph.vertices[nd].negPosition ← position;

ENDCASE => ERROR;

}; --SetNodePosition --

FindRoot: PUBLIC PROC[grph: Ref, which: GraphDirection] RETURNS[nd: NodeIndex] = {

found: BOOL ← FALSE;

SELECT which FROM

pos => FOR i: NAT IN [1..grph.size] DO

IF grph.vertices[i].posInCount = 0 THEN {

IF found THEN {

ERROR FindRootError[MulitpleRoots]} ELSE {found ← TRUE; nd ← i}}

ENDLOOP;

neg => FOR i: NAT IN [1..grph.size] DO

IF grph.vertices[i].negInCount = 0 THEN {

IF found THEN {

ERROR FindRootError[MulitpleRoots]} ELSE {found ← TRUE; nd ← i}}

ENDLOOP;

ENDCASE => ERROR;

IF found THEN NULL ELSE {ERROR FindRootError[NoRoot]};

}; -- FindRoot --

GetCh: PUBLIC PROC[grph: Ref, nd: NodeIndex] RETURNS [REF] ={

RETURN [grph.vertices[nd].ch]}; --GetCh--

Chs: PUBLIC PROC [grph: Ref, p: EachChAction] RETURNS [BOOL] ={

FOR i: NAT IN [1..grph.size] DO

IF p[grph.vertices[i].ch] THEN RETURN [FALSE]

ENDLOOP;

RETURN[TRUE]}; --Chs--

END.