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(*
*
* Begin of Skeleton
*
*)
(* ****************************************************************
Pascal Skeleton Parser FOR matrix tables
This is not a sample program, but rather the parser skeleton
to be included in the generated code.
Modify at your own risk.
Copyright (c), 1985-2016 Jaime Garza
***************************************************************** *)
CONST
ERROR_FAIL = 0;
ERROR_RE_ATTEMPT = 1;
(* Global variables *)
VAR
sStxStack : Array[0..STACK_DEPTH] of integer; (* SState stack. Internal use *)
StxSym : LongInt; (* Actual scanner symbol. Internal usage *)
StxState : integer; (* Current automaton state. Internal usage *)
StxErrors : Integer; (* Counts the number of errors. User can read *)
StxErrorFlag: integer; (* Recuperation machinery state. Internal usage *)
(* These functions must be provided by the user *)
FUNCTION StxError(StxState:INTEGER; StxSym:INTEGER; pStxStack:INTEGER; aMessage:STRING):INTEGER; FORWARD;
{$IFDEF DEBUG}
FUNCTION StxToString(value:TSTACK):STRING; FORWARD;
{$ENDIF}
(*
* ==========================================================
* Regular Expressions
* ==========================================================
*)
VAR
StxEdgeIndex:INTEGER = 0;
(*
checks one transition
*)
FUNCTION StxMatchesWholeTransition:BOOLEAN;
VAR
transitionSize:INTEGER;
negate:BOOLEAN;
matchesTransition:BOOLEAN;
j:INTEGER;
rangeStart:CHAR;
rangeEnd:CHAR;
BEGIN
transitionSize := StxEdges[StxEdgeIndex];
StxEdgeIndex := StxEdgeIndex + 1;
negate := false;
if transitionSize < 0
then begin
negate := true;
transitionSize := -transitionSize;
end;
matchesTransition := false;
if transitionSize = 0
then begin (* ANY match *)
matchesTransition := StxChar <> CHR(0);
end
else begin
(* all elements of one transition *)
for j := 0 to transitionSize-1 do
begin
rangeStart := CHR(StxEdges[StxEdgeIndex]);
rangeEnd := CHR(StxEdges[StxEdgeIndex + 1]);
StxEdgeIndex := StxEdgeIndex + 2;
if (StxChar >= rangeStart) AND (StxChar <= rangeEnd)
then matchesTransition := true;
end; (*FOR*)
end;
if negate
then matchesTransition := NOT matchesTransition;
if StxChar = CHR(0)
then StxMatchesWholeTransition := false
else StxMatchesWholeTransition := matchesTransition
END;
(*
tries to match a regular expression
*)
FUNCTION StxMatchesRegex(vertex:INTEGER):BOOLEAN;
VAR
accept:BOOLEAN;
stop:BOOLEAN;
numTransitions:INTEGER;
matchedOneTransition:BOOLEAN;
i:INTEGER;
newVertex:INTEGER;
matchesTransition:BOOLEAN;
BEGIN
accept := false;
stop := false;
StxRecognized := '';
repeat
accept := false;
StxEdgeIndex := StxVertices[vertex];
if StxEdgeIndex < 0
then begin
accept := true;
StxEdgeIndex := -StxEdgeIndex;
end;
numTransitions := StxEdges[StxEdgeIndex];
StxEdgeIndex := StxEdgeIndex + 1;
matchedOneTransition := false;
for i := 0 to numTransitions-1 do
begin
(* each transition *)
newVertex := StxEdges[StxEdgeIndex];
StxEdgeIndex := StxEdgeIndex + 1;
matchesTransition := StxMatchesWholeTransition;
if matchesTransition
then begin
StxRecognized := StxRecognized + StxChar;
StxChar := StxNextChar;
vertex := newVertex;
matchedOneTransition := true;
break; (* found a matching transition. new vertex *)
end;
end;
if NOT matchedOneTransition
then begin
if accept
then begin
exit(true);
end
else begin
(* backtrack characters *)
for i := LENGTH(StxRecognized) DOWNTO 1 do
begin
StxUngetChar(StxChar);
StxChar := StxRecognized[i];
end;
stop := true;
end;
end;
until stop;
StxMatchesRegex := false;
END;
(*
returns the name of a token, given the token number
*)
FUNCTION StxGetTokenName(token:INTEGER) : STRING;
VAR
i : INTEGER;
BEGIN
FOR i := 0 TO TOKENS-1 DO
BEGIN
IF StxTokenDefs[i].token = token
THEN BEGIN
StxGetTokenName := StxTokenDefs[i].name;
EXIT;
END;
END;
StxGetTokenName := 'UNKNOWN TOKEN';
END;
(*
Find the index of a token
*)
FUNCTION StxGetTokenIndex(token:LONGINT) : INTEGER;
VAR
i : INTEGER;
BEGIN
FOR i := 0 TO TOKENS-1 DO
BEGIN
IF StxTokenDefs[i].token = token
THEN BEGIN
StxGetTokenIndex := i;
EXIT;
END;
END;
StxGetTokenIndex := -1;
END;
(*
This routine maps a state and a token to a new state on the action table
*)
FUNCTION StxAction(state:INTEGER; symbol:LONGINT) : LONGINT;
VAR
index : INTEGER;
BEGIN
index := StxGetTokenIndex(symbol);
StxAction := StxParsingTable[state][index];
END;
(*
This routine maps a origin state to a destination state
using the symbol position
*)
FUNCTION StxGoto(state:INTEGER; symbol:INTEGER): INTEGER;
VAR
index : INTEGER;
BEGIN
index := symbol;
StxGoTo := StxParsingTable[state][index];
END;
(*
This routine prints the contents of the parsing stack
*)
{$IFDEF DEBUG}
PROCEDURE StxPrintStack;
VAR
i:integer;
BEGIN
writeln('Stack pointer = ', pStxStack);
write('States: [');
FOR i:=0 to pStxStack DO
write(sStxStack[i], ' ');
writeln(']<--Top Of Stack (', pStxStack, ')');
write('Values: [');
FOR i:=0 to pStxStack DO
write('|', StxToString(StxStack[i]),'| ');
writeln(']<--Top Of Stack (', pStxStack, ')');
END;
{$ENDIF}
(*
Get the error message FOR the current state
*)
FUNCTION StxErrorMessage: STRING;
VAR
msgIndex : INTEGER;
BEGIN
msgIndex := StxParsingError[StxState];
IF msgIndex >= 0
THEN StxErrorMessage := StxErrorTable[msgIndex]
ELSE StxErrorMessage := 'Syntax error';
END;
(*
Does a shift operation. Puts a new state on the top of the stack
*)
FUNCTION StxShift(sym:LongInt; state:integer):BOOLEAN;
BEGIN
IF pStxStack >= STACK_DEPTH-1
THEN StxShift := FALSE
ELSE BEGIN
pStxStack := pStxStack + 1;
sStxStack[pStxStack] := state;
StxStack[pStxStack] := StxValue;
StxState := state;
StxShift := TRUE;
{$IFDEF DEBUG}
writeln('Shift to ', state, ' with ', sym);
StxPrintStack;
{$ENDIF}
END;
END;
(*
Recognizes a rule an removes all its elements from the stack
*)
FUNCTION StxReduce(sym:LongInt; rule:integer):BOOLEAN;
BEGIN
{$IFDEF DEBUG}
writeln('Reduce on rule ', rule, ' with symbol ', sym);
{$ENDIF}
IF Not StxCode(rule)
THEN StxReduce := FALSE
ELSE BEGIN
pStxStack := pStxStack - StxGrammarTable[rule].reductions;
sStxStack[pStxStack+1] :=
StxGoto(sStxStack[pStxStack], StxGrammarTable[rule].symbol);
pStxStack := pStxStack+1;
StxState := sStxStack[pStxStack];
StxReduce := TRUE;
{$IFDEF DEBUG}
StxPrintStack;
{$ENDIF}
END;
END;
(*
Recover from a syntax error removing stack states/symbols, and removing
input tokens. The array StxRecover contains the tokens that bound
the error
*)
FUNCTION StxRecover: BOOLEAN;
VAR
i, acc : INTEGER;
found : BOOLEAN;
BEGIN
StxRecover := TRUE;
CASE StxErrorFlag OF
0, 1, 2: (* three attempts before dropping the symbol *)
BEGIN
IF StxErrorFlag = 0
THEN BEGIN
IF StxError(StxState, StxSym, pStxStack, StxErrorMessage()) = ERROR_FAIL
THEN BEGIN
StxRecover := FALSE;
EXIT;
END;
END;
StxErrorFlag := 3; (* remove the symbol *)
WHILE pStxStack >= 0 DO
BEGIN
(* Look if the state on the stack's top has a transition with one of
the recovering elements in StxRecoverTable *)
found := FALSE;
FOR i:=0 to RECOVERS-1 DO
BEGIN
acc := StxAction(StxState, StxRecoverTable[i]);
IF acc > 0 (* shift valido *)
THEN BEGIN
StxRecover := StxShift(StxRecoverTable[i], acc);
found := TRUE;
EXIT;
END;
END;
IF NOT found
THEN BEGIN
{$IFDEF DEBUG}
writeln('Recover removing state ', StxState,
' and go to state ', sStxStack[pStxStack-1]);
{$ENDIF}
pStxStack := pStxStack - 1;
StxState := sStxStack[pStxStack];
END; (*IF*)
END; (*WHILE*)
pStxStack := 0;
StxRecover := FALSE;
END; (*CASE 0, 1 y 2*)
3: (* I need to drop the current token *)
BEGIN
{$IFDEF DEBUG}
writeln('Recover removing symbol ', StxSym);
{$ENDIF}
IF StxSym = 0 (* End of input string *)
THEN StxRecover := FALSE
ELSE BEGIN
StxSym := StxLexer;
StxRecover := TRUE;
END;
END; (* CASE *)
END; (* CASE *)
END; (* StxRecover *)
(*
Main parser routine, uses Shift, Reduce and Recover
*)
FUNCTION StxParse: BOOLEAN;
VAR
action: LongInt;
BEGIN
pStxStack := 0;
sStxStack[0] := 0;
StxChar := StxNextChar;
StxSym := StxLexer;
StxState := 0;
StxErrorFlag := 0;
WHILE TRUE do
BEGIN
action := StxAction(StxState, StxSym);
IF action = ACCEPT
THEN BEGIN
{$IFDEF DEBUG}
writeln('Accepted');
{$ENDIF}
StxParse := TRUE;
EXIT;
END
ELSE IF action > 0
THEN BEGIN
IF Not StxShift(StxSym, action)
THEN BEGIN
StxParse := FALSE;
EXIT;
END;
StxSym := StxLexer;
IF StxErrorFlag > 0
THEN StxErrorFlag := StxErrorFlag - 1; (* properly recovering from error *)
END
ELSE IF action < 0
THEN BEGIN
IF Not StxReduce(StxSym, -action)
THEN BEGIN
IF StxErrorFlag = -1
THEN BEGIN
IF NOT StxRecover
THEN BEGIN
StxParse := FALSE;
EXIT;
END;
END
ELSE BEGIN
StxParse := FALSE;
EXIT;
END;
END
END
ELSE BEGIN (* error *)
IF not StxRecover
THEN BEGIN
StxParse := FALSE;
EXIT;
END;
END;
END; (* while *)
END;
FUNCTION StxGetResult : TSTACK;
BEGIN
StxGetResult := StxStack[pStxStack];
END;
(* End of parser *)