diff options
Diffstat (limited to 'generic')
-rw-r--r-- | generic/tclCompExpr.c | 453 |
1 files changed, 251 insertions, 202 deletions
diff --git a/generic/tclCompExpr.c b/generic/tclCompExpr.c index bab56f5..3304b51 100644 --- a/generic/tclCompExpr.c +++ b/generic/tclCompExpr.c @@ -12,7 +12,7 @@ * See the file "license.terms" for information on usage and redistribution of * this file, and for a DISCLAIMER OF ALL WARRANTIES. * - * RCS: @(#) $Id: tclCompExpr.c,v 1.69 2007/07/16 19:50:46 dgp Exp $ + * RCS: @(#) $Id: tclCompExpr.c,v 1.70 2007/07/17 19:18:54 dgp Exp $ */ #include "tclInt.h" @@ -29,7 +29,10 @@ typedef struct OpNode { int left; /* "Pointer" to the left operand. */ int right; /* "Pointer" to the right operand. */ - int parent; /* "Pointer" to the parent operand. */ + union { + int parent; /* "Pointer" to the parent operand. */ + int prev; /* "Pointer" joining incomplete tree stack */ + } p; unsigned char lexeme; /* Code that identifies the operator. */ unsigned char precedence; /* Precedence of the operator */ } OpNode; @@ -83,12 +86,17 @@ enum OperandTypes { * the inorder traversals of the completed tree we perform are known to visit * the leaves in the same order as the original parse. * - * Those OpNodes that are themselves (roots of subexpression trees that are) - * operands of some operator store in their parent field a "pointer" to the - * OpNode of that operator. The parent field permits a destructive inorder - * traversal of the tree within a non-recursive routine (ConvertTreeToTokens() - * and CompileExprTree()). This means that even expression trees of great - * depth pose no risk of blowing the C stack. + * In a completed parse tree, those OpNodes that are themselves (roots of + * subexpression trees that are) operands of some operator store in their + * p.parent field a "pointer" to the OpNode of that operator. The p.parent + * field permits a destructive inorder traversal of the tree within a + * non-recursive routine (ConvertTreeToTokens() and CompileExprTree()). This + * means that even expression trees of great depth pose no risk of blowing + * the C stack. + * + * While the parse tree is being constructed, the same memory space is used + * to hold the p.prev field which chains together a stack of incomplete + * trees awaiting their right operands. * * The lexeme field is filled in with the lexeme of the operator that is * returned by the ParseLexeme() routine. Only lexemes for unary and @@ -458,22 +466,27 @@ ParseExpr( * for most expressions to parse with no need * for array growth and reallocation. */ int nodesUsed = 0; /* Number of OpNodes filled. */ - int code = TCL_OK; /* Return code */ int scanned = 0; /* Capture number of byte scanned by * parsing routines. */ - unsigned char lexeme = START; /* Most recent lexeme parsed. */ - int lastOpen = 0; /* Index of the OpNode of the OPEN_PAREN - * operator we most recently matched. */ - int lastParsed = 0; /* Stores info about what the lexeme parsed + unsigned char lexeme; /* Most recent lexeme parsed. */ + int lastParsed; /* Stores info about what the lexeme parsed * the previous pass through the parsing loop * was. If it was an operator, lastParsed is * the index of the OpNode for that operator. - * If it was not and operator, lastParsed holds + * If it was not an operator, lastParsed holds * an OperandTypes value encoding what we - * need to know about it. The initial value - * is 0 indicating that as we start the "last - * thing we parsed" was the START lexeme stored - * in node 0. */ + * need to know about it. */ + int incomplete; /* Index of the most recent incomplete tree + * in the OpNode array. Heads a stack of + * incomplete trees linked by p.prev. */ + int complete = OT_NONE; /* "Index" of the complete tree (that is, a + * complete subexpression) determined at the + * moment. OT_NONE is a nonsense value + * used only to silence compiler warnings. + * During a parse, complete will always hold + * an index or an OperandTypes value pointing + * to an actual leaf at the time the complete + * tree is needed. */ /* These variables control generation of the error message. */ Tcl_Obj *msg = NULL; /* The error message. */ @@ -504,22 +517,25 @@ ParseExpr( nodes = (OpNode *) attemptckalloc(nodesAvailable * sizeof(OpNode)); if (nodes == NULL) { TclNewLiteralStringObj(msg, "not enough memory to parse expression"); - code = TCL_ERROR; - } else { - /* - * Initialize the parse tree with the special "START" node. - */ - - nodes->lexeme = lexeme; - nodes->precedence = prec[lexeme]; - nodes->left = OT_NONE; - nodes->right = OT_NONE; - /* TODO: explain. */ - nodes->parent = -1; - nodesUsed++; + goto error; } - while ((code == TCL_OK) && (lexeme != END)) { + /* Initialize the parse tree with the special "START" node. */ + nodes->lexeme = START; + nodes->precedence = prec[START]; + nodes->left = OT_NONE; + nodes->right = OT_NONE; + incomplete = lastParsed = nodesUsed; + nodesUsed++; + + /* + * Main parsing loop parses one lexeme per iteration. We exit the + * loop only when there's a syntax error with a "goto error" which + * takes us to the error handling code following the loop, or when + * we've successfully complete the parse and we return to the caller. + */ + + while (1) { OpNode *nodePtr; /* Points to the OpNode we may fill this * pass through the loop. */ Tcl_Obj *literal; /* Filled by the ParseLexeme() call when @@ -549,47 +565,40 @@ ParseExpr( if (newPtr == NULL) { TclNewLiteralStringObj(msg, "not enough memory to parse expression"); - code = TCL_ERROR; - continue; + goto error; } nodesAvailable = size; nodes = newPtr; } nodePtr = nodes + nodesUsed; - /* - * Skip white space between lexemes. - */ - + /* Skip white space between lexemes. */ scanned = TclParseAllWhiteSpace(start, numBytes); start += scanned; numBytes -= scanned; scanned = ParseLexeme(start, numBytes, &lexeme, &literal); - /* - * Use context to categorize the lexemes that are ambiguous. - */ - + /* Use context to categorize the lexemes that are ambiguous. */ if ((NODE_TYPE & lexeme) == 0) { switch (lexeme) { case INVALID: msg = Tcl_ObjPrintf( "invalid character \"%.*s\"", scanned, start); - code = TCL_ERROR; - continue; + goto error; case INCOMPLETE: msg = Tcl_ObjPrintf( "incomplete operator \"%.*s\"", scanned, start); - code = TCL_ERROR; - continue; + goto error; case BAREWORD: + /* * Most barewords in an expression are a syntax error. * The exceptions are that when a bareword is followed by * an open paren, it might be a function call, and when the * bareword is a legal literal boolean value, we accept that * as well. + */ if (start[scanned+TclParseAllWhiteSpace( start+scanned, numBytes-scanned)] == '(') { @@ -601,6 +610,7 @@ ParseExpr( * it, so we keep a separate list of all the function * names we've parsed in the order we found them. */ + Tcl_ListObjAppendElement(NULL, funcList, literal); } else { int b; @@ -622,18 +632,19 @@ ParseExpr( " or \"%.*s%s(...)\" or ...", (scanned < limit) ? scanned : limit - 3, start, (scanned < limit) ? "" : "..."); - code = TCL_ERROR; - continue; + goto error; } } break; case PLUS: case MINUS: if (IsOperator(lastParsed)) { + /* * A "+" or "-" coming just after another operator * must be interpreted as a unary operator. */ + lexeme |= UNARY; } else { lexeme |= BINARY; @@ -641,10 +652,7 @@ ParseExpr( } } /* Uncategorized lexemes */ - /* - * Handle lexeme based on its category. - */ - + /* Handle lexeme based on its category. */ switch (NODE_TYPE & lexeme) { /* @@ -658,6 +666,7 @@ ParseExpr( Tcl_Token *tokenPtr; const char *end = start; int wordIndex; + int code = TCL_OK; /* * A leaf operand appearing just after something that's not an @@ -678,19 +687,19 @@ ParseExpr( scanned = 0; insertMark = 1; parsePtr->errorType = TCL_PARSE_BAD_NUMBER; - code = TCL_ERROR; - /* - * Delay our escape from the parse loop until any literal - * can be appended to litList, making it available to our - * caller to be freed, to avoid leaking it. - */ + + /* Free any literal to avoid a memleak. */ + if ((lexeme == NUMBER) || (lexeme == BOOLEAN)) { + Tcl_DecrRefCount(literal); + } + goto error; } switch (lexeme) { case NUMBER: case BOOLEAN: Tcl_ListObjAppendElement(NULL, litList, literal); - lastParsed = OT_LITERAL; + complete = lastParsed = OT_LITERAL; start += scanned; numBytes -= scanned; continue; @@ -698,11 +707,6 @@ ParseExpr( break; } - if (code != TCL_OK) { - /* Escaping the loop due to syntax error is fine now. */ - continue; - } - /* * Remaining LEAF cases may involve filling Tcl_Tokens, so * make room for at least 2 more tokens. @@ -741,8 +745,7 @@ ParseExpr( tokenPtr = parsePtr->tokenPtr + wordIndex + 1; if (code == TCL_OK && tokenPtr->type != TCL_TOKEN_VARIABLE) { TclNewLiteralStringObj(msg, "invalid character \"$\""); - code = TCL_ERROR; - continue; + goto error; } scanned = tokenPtr->size; break; @@ -793,6 +796,7 @@ ParseExpr( } } if (code != TCL_OK) { + /* * Here we handle all the syntax errors generated by * the Tcl_Token generating parsing routines called in the @@ -808,10 +812,10 @@ ParseExpr( * the syntax error is sure to appear in it, even if the * quoted expression is truncated. */ + start = parsePtr->term; scanned = parsePtr->incomplete; - /* Escape the parse loop to report the syntax error. */ - continue; + goto error; } tokenPtr = parsePtr->tokenPtr + wordIndex; @@ -839,52 +843,55 @@ ParseExpr( literal = Tcl_NewObj(); if (TclWordKnownAtCompileTime(tokenPtr, literal)) { Tcl_ListObjAppendElement(NULL, litList, literal); - lastParsed = OT_LITERAL; + complete = lastParsed = OT_LITERAL; parsePtr->numTokens = wordIndex; break; } Tcl_DecrRefCount(literal); } - lastParsed = OT_TOKENS; + complete = lastParsed = OT_TOKENS; break; } /* case LEAF */ case UNARY: + /* * A unary operator appearing just after something that's not an * operator is a syntax error -- something trying to be the left * operand of an operator that doesn't take one. */ + if (NotOperator(lastParsed)) { msg = Tcl_ObjPrintf("missing operator at %s", mark); scanned = 0; insertMark = 1; - code = TCL_ERROR; - /* Escape the parse loop to report the syntax error. */ - continue; + goto error; } + /* Create an OpNode for the unary operator */ nodePtr->lexeme = lexeme; /* Remember the operator... */ nodePtr->precedence = prec[lexeme]; /* ... and its precedence. */ nodePtr->left = OT_NONE; /* No left operand */ nodePtr->right = OT_NONE; /* Right operand not * yet known. */ - /* TODO: explain */ - nodePtr->parent = nodePtr - nodes - 1; + /* - * Remember this unary operator as the last thing parsed for - * the next pass through the loop. + * This unary operator is a new incomplete tree, so push it + * onto our stack of incomplete trees. Also remember it as + * the last lexeme we parsed. */ - lastParsed = nodesUsed; + + nodePtr->p.prev = incomplete; + incomplete = lastParsed = nodesUsed; nodesUsed++; break; case BINARY: { - OpNode *otherPtr = NULL; + OpNode *incompletePtr; unsigned char precedence = prec[lexeme]; /* - * A binary operand appearing just after another operator is a + * A binary operator appearing just after another operator is a * syntax error -- one of the two operators is missing an operand. */ @@ -892,22 +899,28 @@ ParseExpr( if ((lexeme == CLOSE_PAREN) && (nodePtr[-1].lexeme == OPEN_PAREN)) { if (nodePtr[-2].lexeme == FUNCTION) { + /* * Normally, "()" is a syntax error, but as a special * case accept it as an argument list for a function. + * Treat this as a special LEAF lexeme, and restart + * the parsing loop with zero characters scanned. + * We'll parse the ")" again the next time through, + * but with the OT_EMPTY leaf as the subexpression + * between the parens. */ scanned = 0; + complete = lastParsed = OT_EMPTY; + /* TODO: explain */ - lastParsed = OT_EMPTY; nodePtr[-1].left--; break; } msg = Tcl_ObjPrintf("empty subexpression at %s", mark); scanned = 0; insertMark = 1; - code = TCL_ERROR; - continue; + goto error; } if (nodePtr[-1].precedence > precedence) { @@ -939,199 +952,240 @@ ParseExpr( scanned = 0; insertMark = 1; } - code = TCL_ERROR; - continue; + goto error; } - /* TODO: explain */ - if (lastParsed == OT_NONE) { - otherPtr = nodes + lastOpen - 1; - lastParsed = lastOpen; - } else { - otherPtr = nodePtr - 1; - } + /* + * Here is where the tree comes together. At this point, we + * have a sequence of incomplete trees corresponding to + * substrings that are incomplete expressions, followed by + * a complete tree corresponding to a substring that is itself + * a complete expression, followed by the binary operator we have + * just parsed. The incomplete trees can each be completed by + * adding a right operand. + * + * To illustrate with an example, when we parse the expression + * "1+2*3-4" and we reach this point having just parsed the "-" + * operator, we have these incomplete trees: START, "1+", and + * "2*". Next we have the complete subexpression "3". Last is + * the "-" we've just parsed. + * + * The next step is to join our complete tree to an operator. + * The choice is governed by the precedence and associativity + * of the competing operators. If we connect it as the right + * operand of our most recent incomplete tree, we get a new + * complete tree, and we can repeat the process. The while + * loop following repeats this until precedence indicates it + * is time to join the complete tree as the left operand of + * the just parsed binary operator. + * + * Continuing the example, the first pass through the loop + * will join "3" to "2*"; the next pass will join "2*3" to + * "1+". Then we'll exit the loop and join "1+2*3" to "-". + * When we return to parse another lexeme, our incomplete + * tree list is START and "1+2*3-". + */ + while (1) { - /* - * lastParsed is "index" of item to be linked. - * otherPtr points to competing operator. - */ + incompletePtr = nodes + incomplete; - if (otherPtr->precedence < precedence) { + if (incompletePtr->precedence < precedence) { break; } - if (otherPtr->precedence == precedence) { - /* - * Right association rules for exponentiation. - */ + if (incompletePtr->precedence == precedence) { + /* Right association rules for exponentiation. */ if (lexeme == EXPON) { break; } /* - * Special association rules for the ternary operators. + * Special association rules for the conditional operators. * The "?" and ":" operators have equal precedence, but * must be linked up in sensible pairs. */ - if ((otherPtr->lexeme == QUESTION) - && (NotOperator(lastParsed) - || (nodes[lastParsed].lexeme != COLON))) { + if ((incompletePtr->lexeme == QUESTION) + && (NotOperator(complete) + || (nodes[complete].lexeme != COLON))) { break; } - if ((otherPtr->lexeme == COLON) && (lexeme == QUESTION)) { + if ((incompletePtr->lexeme == COLON) + && (lexeme == QUESTION)) { break; } } - /* - * We should link the lastParsed item to the otherPtr as its - * right operand. First make some syntax checks. - */ + /* Some special syntax checks... */ - if ((otherPtr->lexeme == OPEN_PAREN) + /* Parens must balance */ + if ((incompletePtr->lexeme == OPEN_PAREN) && (lexeme != CLOSE_PAREN)) { TclNewLiteralStringObj(msg, "unbalanced open paren"); parsePtr->errorType = TCL_PARSE_MISSING_PAREN; - code = TCL_ERROR; - break; + goto error; } - if ((otherPtr->lexeme == QUESTION) - && (NotOperator(lastParsed) - || (nodes[lastParsed].lexeme != COLON))) { + + /* Right operand of "?" must be ":" */ + if ((incompletePtr->lexeme == QUESTION) + && (NotOperator(complete) + || (nodes[complete].lexeme != COLON))) { msg = Tcl_ObjPrintf( "missing operator \":\" at %s", mark); scanned = 0; insertMark = 1; - code = TCL_ERROR; - break; + goto error; } - if (IsOperator(lastParsed) - && (nodes[lastParsed].lexeme == COLON) - && (otherPtr->lexeme != QUESTION)) { + + /* Operator ":" may only be right operand of "?" */ + if (IsOperator(complete) + && (nodes[complete].lexeme == COLON) + && (incompletePtr->lexeme != QUESTION)) { TclNewLiteralStringObj(msg, - "unexpected operator \":\" without preceding \"?\""); - code = TCL_ERROR; - break; + "unexpected operator \":\" " + "without preceding \"?\""); + goto error; } /* - * Link orphan as right operand of otherPtr. + * Attach complete tree as right operand of most recent + * incomplete tree. */ - otherPtr->right = lastParsed; - if (lastParsed >= 0) { - nodes[lastParsed].parent = otherPtr - nodes; + incompletePtr->right = complete; + if (IsOperator(complete)) { + nodes[complete].p.parent = incomplete; } - lastParsed = otherPtr - nodes; - if (otherPtr->lexeme == OPEN_PAREN) { + if (incompletePtr->lexeme == START) { + /* - * CLOSE_PAREN can only close one OPEN_PAREN. + * Completing the START tree indicates we're done. + * Transfer the parse tree to the caller and return. */ - break; + *opTreePtr = nodes; + return TCL_OK; } - if (otherPtr->lexeme == START) { - /* - * Don't backtrack beyond the start. - */ + /* + * With a right operand attached, last incomplete tree has + * become the complete tree. Pop it from the incomplete + * tree stack. + */ + complete = incomplete; + incomplete = incompletePtr->p.prev; + + /* CLOSE_PAREN can only close one OPEN_PAREN. */ + if (incompletePtr->lexeme == OPEN_PAREN) { break; } - otherPtr = nodes + otherPtr->parent; - } - if (code != TCL_OK) { - continue; } + /* More syntax checks... */ + + /* Parens must balance. */ if (lexeme == CLOSE_PAREN) { - if (otherPtr->lexeme == START) { + if (incompletePtr->lexeme != OPEN_PAREN) { TclNewLiteralStringObj(msg, "unbalanced close paren"); - code = TCL_ERROR; - continue; + goto error; } - lastParsed = OT_NONE; - lastOpen = otherPtr - nodes; - otherPtr->left++; - - /* - * Create no node for a CLOSE_PAREN lexeme. - */ - - break; } + + /* Commas must appear only in function argument lists. */ if (lexeme == COMMA) { - if ((otherPtr->lexeme != OPEN_PAREN) - || (otherPtr[-1].lexeme != FUNCTION)) { + if ((incompletePtr->lexeme != OPEN_PAREN) + || (incompletePtr[-1].lexeme != FUNCTION)) { TclNewLiteralStringObj(msg, "unexpected \",\" outside function argument list"); - code = TCL_ERROR; - continue; + goto error; } - otherPtr->left++; + + /* TODO: explain */ + incompletePtr->left++; } - if (IsOperator(lastParsed) && (nodes[lastParsed].lexeme == COLON)) { + + /* Operator ":" may only be right operand of "?" */ + if (IsOperator(complete) && (nodes[complete].lexeme == COLON)) { TclNewLiteralStringObj(msg, "unexpected operator \":\" without preceding \"?\""); - code = TCL_ERROR; - continue; - } - if (lexeme == END) { - continue; + goto error; } - /* - * Link orphan as left operand of new node. - */ + /* Create no node for a CLOSE_PAREN lexeme. */ + if (lexeme == CLOSE_PAREN) { + + /* TODO: explain */ + incompletePtr->left++; + break; + } + /* Link complete tree as left operand of new node. */ nodePtr->lexeme = lexeme; nodePtr->precedence = precedence; - nodePtr->right = -1; - nodePtr->left = lastParsed; - if (lastParsed < 0) { - nodePtr->parent = nodePtr - nodes - 1; - } else { - nodePtr->parent = nodes[lastParsed].parent; - nodes[lastParsed].parent = nodePtr - nodes; + nodePtr->right = OT_NONE; + nodePtr->left = complete; + if (IsOperator(complete)) { + nodes[complete].p.parent = nodesUsed; } - lastParsed = nodesUsed; + + /* + * With a left operand attached and a right operand missing, + * the just-parsed binary operator is root of a new incomplete + * tree. Push it onto the stack of incomplete trees. + */ + + nodePtr->p.prev = incomplete; + incomplete = lastParsed = nodesUsed; nodesUsed++; break; } /* case BINARY */ } /* lexeme handler */ /* Advance past the just-parsed lexeme */ - start += scanned; numBytes -= scanned; } /* main parsing loop */ - /* In case of any error, we free any partial parse tree we've built. */ - if (code != TCL_OK && nodes != NULL) { + error: + + /* + * We only get here if there's been an error. + * Any errors that didn't get a suitable parsePtr->errorType, + * get recorded as syntax errors. + */ + + if (parsePtr->errorType == TCL_PARSE_SUCCESS) { + parsePtr->errorType = TCL_PARSE_SYNTAX; + } + + /* Free any partial parse tree we've built. */ + if (nodes != NULL) { ckfree((char*) nodes); } - if (code == TCL_OK) { - /* No error, transfer the parse tree to the caller */ - *opTreePtr = nodes; - } else if (interp == NULL) { + + if (interp == NULL) { /* Nowhere to report an error message, so just free it */ if (msg) { Tcl_DecrRefCount(msg); } } else { + /* * Construct the complete error message. Start with the simple * error message, pulled from the interp result if necessary... */ + if (msg == NULL) { msg = Tcl_GetObjResult(interp); } + /* * Add a detailed quote from the bad expression, displaying and * sometimes marking the precise location of the syntax error. */ + Tcl_AppendPrintfToObj(msg, "\nin expression \"%s%.*s%.*s%s%s%.*s%s\"", ((start - limit) < parsePtr->string) ? "" : "...", ((start - limit) < parsePtr->string) @@ -1144,6 +1198,7 @@ ParseExpr( ? parsePtr->end - (start + scanned) : limit-3, start + scanned, (start + scanned + limit > parsePtr->end) ? "" : "..."); + /* Next, append any postscript message. */ if (post != NULL) { Tcl_AppendToObj(msg, ";\n", -1); @@ -1151,6 +1206,7 @@ ParseExpr( Tcl_DecrRefCount(post); } Tcl_SetObjResult(interp, msg); + /* Finally, place context information in the errorInfo. */ numBytes = parsePtr->end - parsePtr->string; Tcl_AppendObjToErrorInfo(interp, Tcl_ObjPrintf( @@ -1159,14 +1215,7 @@ ParseExpr( parsePtr->string, (numBytes < limit) ? "" : "...")); } - /* - * Any errors that didn't get a suitable parsePtr->errorType, - * get recorded as syntax errors. - */ - if (code != TCL_OK && parsePtr->errorType == TCL_PARSE_SUCCESS) { - parsePtr->errorType = TCL_PARSE_SYNTAX; - } - return code; + return TCL_ERROR; } /* @@ -1385,7 +1434,7 @@ ConvertTreeToTokens( destPtr->size = start - destPtr->start; destPtr->numComponents = parsePtr->numTokens - tokenIdx - 1; } - nodePtr = nodes + nodePtr->parent; + nodePtr = nodes + nodePtr->p.parent; } break; case BINARY: @@ -1473,7 +1522,7 @@ ConvertTreeToTokens( destPtr->size = start - destPtr->start; destPtr->numComponents = parsePtr->numTokens-tokenIdx-1; } - nodePtr = nodes + nodePtr->parent; + nodePtr = nodes + nodePtr->p.parent; } break; } @@ -1983,7 +2032,7 @@ CompileExprTree( TclEmitOpcode(instruction[nodePtr->lexeme], envPtr); *convertPtr = 0; } - nodePtr = nodes + nodePtr->parent; + nodePtr = nodes + nodePtr->p.parent; } break; case BINARY: @@ -2128,7 +2177,7 @@ CompileExprTree( jumpPtr = jumpPtr->next; TclStackFree(interp, freePtr); } - nodePtr = nodes + nodePtr->parent; + nodePtr = nodes + nodePtr->p.parent; } break; } @@ -2188,7 +2237,7 @@ TclSingleOpCmd( nodes[1].lexeme = lexeme; nodes[1].left = OT_LITERAL; nodes[1].right = OT_LITERAL; - nodes[1].parent = 0; + nodes[1].p.parent = 0; return OpCmd(interp, nodes, objv+1); } @@ -2227,10 +2276,10 @@ TclSortingOpCmd( litObjv[2*(i-1)] = objv[i]; nodes[2*(i-1)].lexeme = AND; nodes[2*(i-1)].left = lastAnd; - nodes[lastAnd].parent = 2*(i-1); + nodes[lastAnd].p.parent = 2*(i-1); nodes[2*(i-1)].right = 2*(i-1)+1; - nodes[2*(i-1)+1].parent= 2*(i-1); + nodes[2*(i-1)+1].p.parent= 2*(i-1); lastAnd = 2*(i-1); } @@ -2241,7 +2290,7 @@ TclSortingOpCmd( nodes[2*(objc-2)-1].right = OT_LITERAL; nodes[0].right = lastAnd; - nodes[lastAnd].parent = 0; + nodes[lastAnd].p.parent = 0; code = OpCmd(interp, nodes, litObjv); @@ -2285,7 +2334,7 @@ TclVariadicOpCmd( nodes[1].lexeme = lexeme; nodes[1].left = OT_LITERAL; nodes[1].right = OT_LITERAL; - nodes[1].parent = 0; + nodes[1].p.parent = 0; } else { if (lexeme == DIVIDE) { litObjv[0] = Tcl_NewDoubleObj(1.0); @@ -2299,7 +2348,7 @@ TclVariadicOpCmd( nodes[1].lexeme = lexeme; nodes[1].left = OT_LITERAL; nodes[1].right = OT_LITERAL; - nodes[1].parent = 0; + nodes[1].p.parent = 0; } code = OpCmd(interp, nodes, litObjv); @@ -2318,7 +2367,7 @@ TclVariadicOpCmd( nodes[i].left = OT_LITERAL; nodes[i].right = lastOp; if (lastOp >= 0) { - nodes[lastOp].parent = i; + nodes[lastOp].p.parent = i; } lastOp = i; } @@ -2327,14 +2376,14 @@ TclVariadicOpCmd( nodes[i].lexeme = lexeme; nodes[i].left = lastOp; if (lastOp >= 0) { - nodes[lastOp].parent = i; + nodes[lastOp].p.parent = i; } nodes[i].right = OT_LITERAL; lastOp = i; } } nodes[0].right = lastOp; - nodes[lastOp].parent = 0; + nodes[lastOp].p.parent = 0; code = OpCmd(interp, nodes, objv+1); |