/* * tclParse.c -- * * This file contains functions that parse Tcl scripts. They do so in a * general-purpose fashion that can be used for many different purposes, * including compilation, direct execution, code analysis, etc. * * Copyright (c) 1997 Sun Microsystems, Inc. * Copyright (c) 1998-2000 Ajuba Solutions. * Contributions from Don Porter, NIST, 2002. (not subject to US copyright) * * See the file "license.terms" for information on usage and redistribution of * this file, and for a DISCLAIMER OF ALL WARRANTIES. * */ #include "tclInt.h" /* * The following table provides parsing information about each possible 8-bit * character. The table is designed to be referenced with either signed or * unsigned characters, so it has 384 entries. The first 128 entries * correspond to negative character values, the next 256 correspond to * positive character values. The last 128 entries are identical to the first * 128. The table is always indexed with a 128-byte offset (the 128th entry * corresponds to a character value of 0). * * The macro CHAR_TYPE is used to index into the table and return information * about its character argument. The following return values are defined. * * TYPE_NORMAL - All characters that don't have special significance to * the Tcl parser. * TYPE_SPACE - The character is a whitespace character other than * newline. * TYPE_COMMAND_END - Character is newline or semicolon. * TYPE_SUBS - Character begins a substitution or has other special * meaning in ParseTokens: backslash, dollar sign, or * open bracket. * TYPE_QUOTE - Character is a double quote. * TYPE_CLOSE_PAREN - Character is a right parenthesis. * TYPE_CLOSE_BRACK - Character is a right square bracket. * TYPE_BRACE - Character is a curly brace (either left or right). */ #define TYPE_NORMAL 0 #define TYPE_SPACE 0x1 #define TYPE_COMMAND_END 0x2 #define TYPE_SUBS 0x4 #define TYPE_QUOTE 0x8 #define TYPE_CLOSE_PAREN 0x10 #define TYPE_CLOSE_BRACK 0x20 #define TYPE_BRACE 0x40 #define CHAR_TYPE(c) (charTypeTable+128)[(int)(c)] static const char charTypeTable[] = { /* * Negative character values, from -128 to -1: */ TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, /* * Positive character values, from 0-127: */ TYPE_SUBS, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_SPACE, TYPE_COMMAND_END, TYPE_SPACE, TYPE_SPACE, TYPE_SPACE, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_SPACE, TYPE_NORMAL, TYPE_QUOTE, TYPE_NORMAL, TYPE_SUBS, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_CLOSE_PAREN, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_COMMAND_END, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_SUBS, TYPE_SUBS, TYPE_CLOSE_BRACK, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_BRACE, TYPE_NORMAL, TYPE_BRACE, TYPE_NORMAL, TYPE_NORMAL, /* * Large unsigned character values, from 128-255: */ TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, TYPE_NORMAL, }; /* * Prototypes for local functions defined in this file: */ static inline int CommandComplete(const char *script, int numBytes); static int ParseComment(const char *src, int numBytes, Tcl_Parse *parsePtr); static int ParseTokens(const char *src, int numBytes, int mask, int flags, Tcl_Parse *parsePtr); static int ParseWhiteSpace(const char *src, int numBytes, int *incompletePtr, char *typePtr); /* *---------------------------------------------------------------------- * * TclParseInit -- * * Initialize the fields of a Tcl_Parse struct. * * Results: * None. * * Side effects: * The Tcl_Parse struct pointed to by parsePtr gets initialized. * *---------------------------------------------------------------------- */ void TclParseInit( Tcl_Interp *interp, /* Interpreter to use for error reporting */ const char *start, /* Start of string to be parsed. */ int numBytes, /* Total number of bytes in string. If < 0, * the script consists of all bytes up to the * first null character. */ Tcl_Parse *parsePtr) /* Points to struct to initialize */ { parsePtr->numWords = 0; parsePtr->tokenPtr = parsePtr->staticTokens; parsePtr->numTokens = 0; parsePtr->tokensAvailable = NUM_STATIC_TOKENS; parsePtr->string = start; parsePtr->end = start + numBytes; parsePtr->term = parsePtr->end; parsePtr->interp = interp; parsePtr->incomplete = 0; parsePtr->errorType = TCL_PARSE_SUCCESS; } /* *---------------------------------------------------------------------- * * Tcl_ParseCommand -- * * Given a string, this function parses the first Tcl command in the * string and returns information about the structure of the command. * * Results: * The return value is TCL_OK if the command was parsed successfully and * TCL_ERROR otherwise. If an error occurs and interp isn't NULL then an * error message is left in its result. On a successful return, parsePtr * is filled in with information about the command that was parsed. * * Side effects: * If there is insufficient space in parsePtr to hold all the information * about the command, then additional space is malloc-ed. If the function * returns TCL_OK then the caller must eventually invoke Tcl_FreeParse to * release any additional space that was allocated. * *---------------------------------------------------------------------- */ int Tcl_ParseCommand( Tcl_Interp *interp, /* Interpreter to use for error reporting; if * NULL, then no error message is provided. */ const char *start, /* First character of string containing one or * more Tcl commands. */ register int numBytes, /* Total number of bytes in string. If < 0, * the script consists of all bytes up to the * first null character. */ int nested, /* Non-zero means this is a nested command: * close bracket should be considered a * command terminator. If zero, then close * bracket has no special meaning. */ register Tcl_Parse *parsePtr) /* Structure to fill in with information about * the parsed command; any previous * information in the structure is ignored. */ { register const char *src; /* Points to current character in the * command. */ char type; /* Result returned by CHAR_TYPE(*src). */ Tcl_Token *tokenPtr; /* Pointer to token being filled in. */ int wordIndex; /* Index of word token for current word. */ int terminators; /* CHAR_TYPE bits that indicate the end of a * command. */ const char *termPtr; /* Set by Tcl_ParseBraces/QuotedString to * point to char after terminating one. */ int scanned; if ((start == NULL) && (numBytes != 0)) { if (interp != NULL) { Tcl_SetResult(interp, "can't parse a NULL pointer", TCL_STATIC); } return TCL_ERROR; } if (numBytes < 0) { numBytes = strlen(start); } TclParseInit(interp, start, numBytes, parsePtr); parsePtr->commentStart = NULL; parsePtr->commentSize = 0; parsePtr->commandStart = NULL; parsePtr->commandSize = 0; if (nested != 0) { terminators = TYPE_COMMAND_END | TYPE_CLOSE_BRACK; } else { terminators = TYPE_COMMAND_END; } /* * Parse any leading space and comments before the first word of the * command. */ scanned = ParseComment(start, numBytes, parsePtr); src = (start + scanned); numBytes -= scanned; if (numBytes == 0) { if (nested) { parsePtr->incomplete = nested; } } /* * The following loop parses the words of the command, one word in each * iteration through the loop. */ parsePtr->commandStart = src; while (1) { int expandWord = 0; /* * Create the token for the word. */ TclGrowParseTokenArray(parsePtr, 1); wordIndex = parsePtr->numTokens; tokenPtr = &parsePtr->tokenPtr[wordIndex]; tokenPtr->type = TCL_TOKEN_WORD; /* * Skip white space before the word. Also skip a backslash-newline * sequence: it should be treated just like white space. */ scanned = ParseWhiteSpace(src,numBytes, &parsePtr->incomplete, &type); src += scanned; numBytes -= scanned; if (numBytes == 0) { parsePtr->term = src; break; } if ((type & terminators) != 0) { parsePtr->term = src; src++; break; } tokenPtr->start = src; parsePtr->numTokens++; parsePtr->numWords++; /* * At this point the word can have one of four forms: something * enclosed in quotes, something enclosed in braces, and expanding * word, or an unquoted word (anything else). */ parseWord: if (*src == '"') { if (Tcl_ParseQuotedString(interp, src, numBytes, parsePtr, 1, &termPtr) != TCL_OK) { goto error; } src = termPtr; numBytes = parsePtr->end - src; } else if (*src == '{') { int expIdx = wordIndex + 1; Tcl_Token *expPtr; if (Tcl_ParseBraces(interp, src, numBytes, parsePtr, 1, &termPtr) != TCL_OK) { goto error; } src = termPtr; numBytes = parsePtr->end - src; /* * Check whether the braces contained the word expansion prefix * {*} */ expPtr = &parsePtr->tokenPtr[expIdx]; if ((0 == expandWord) /* Haven't seen prefix already */ && (1 == parsePtr->numTokens - expIdx) /* Only one token */ && (((1 == (size_t) expPtr->size) /* Same length as prefix */ && (expPtr->start[0] == '*'))) /* Is the prefix */ && (numBytes > 0) && (0 == ParseWhiteSpace(termPtr, numBytes, &parsePtr->incomplete, &type)) && (type != TYPE_COMMAND_END) /* Non-whitespace follows */) { expandWord = 1; parsePtr->numTokens--; goto parseWord; } } else { /* * This is an unquoted word. Call ParseTokens and let it do all of * the work. */ if (ParseTokens(src, numBytes, TYPE_SPACE|terminators, TCL_SUBST_ALL, parsePtr) != TCL_OK) { goto error; } src = parsePtr->term; numBytes = parsePtr->end - src; } /* * Finish filling in the token for the word and check for the special * case of a word consisting of a single range of literal text. */ tokenPtr = &parsePtr->tokenPtr[wordIndex]; tokenPtr->size = src - tokenPtr->start; tokenPtr->numComponents = parsePtr->numTokens - (wordIndex + 1); if (expandWord) { int i, isLiteral = 1; /* * When a command includes a word that is an expanded literal; for * example, {*}{1 2 3}, the parser performs that expansion * immediately, generating several TCL_TOKEN_SIMPLE_WORDs instead * of a single TCL_TOKEN_EXPAND_WORD that the Tcl_ParseCommand() * caller might have to expand. This notably makes it simpler for * those callers that wish to track line endings, such as those * that implement key parts of TIP 280. * * First check whether the thing to be expanded is a literal, * in the sense of being composed entirely of TCL_TOKEN_TEXT * tokens. */ for (i = 1; i <= tokenPtr->numComponents; i++) { if (tokenPtr[i].type != TCL_TOKEN_TEXT) { isLiteral = 0; break; } } if (isLiteral) { int elemCount = 0, code = TCL_OK, nakedbs = 0; const char *nextElem, *listEnd, *elemStart; /* * The word to be expanded is a literal, so determine the * boundaries of the literal string to be treated as a list * and expanded. That literal string starts at * tokenPtr[1].start, and includes all bytes up to, but not * including (tokenPtr[tokenPtr->numComponents].start + * tokenPtr[tokenPtr->numComponents].size) */ listEnd = (tokenPtr[tokenPtr->numComponents].start + tokenPtr[tokenPtr->numComponents].size); nextElem = tokenPtr[1].start; /* * Step through the literal string, parsing and counting list * elements. */ while (nextElem < listEnd) { int size, brace; code = TclFindElement(NULL, nextElem, listEnd - nextElem, &elemStart, &nextElem, &size, &brace); if (code != TCL_OK) { break; } if (!brace) { const char *s; for(s=elemStart;size>0;s++,size--) { if ((*s)=='\\') { nakedbs=1; break; } } } if (elemStart < listEnd) { elemCount++; } } if ((code != TCL_OK) || nakedbs) { /* * Some list element could not be parsed, or contained * naked backslashes. This means the literal string was * not in fact a valid nor canonical list. Defer the * handling of this to compile/eval time, where code is * already in place to report the "attempt to expand a * non-list" error or expand lists that require * substitution. */ tokenPtr->type = TCL_TOKEN_EXPAND_WORD; } else if (elemCount == 0) { /* * We are expanding a literal empty list. This means that * the expanding word completely disappears, leaving no * word generated this pass through the loop. Adjust * accounting appropriately. */ parsePtr->numWords--; parsePtr->numTokens = wordIndex; } else { /* * Recalculate the number of Tcl_Tokens needed to store * tokens representing the expanded list. */ int growthNeeded = wordIndex + 2*elemCount - parsePtr->numTokens; parsePtr->numWords += elemCount - 1; if (growthNeeded > 0) { TclGrowParseTokenArray(parsePtr, growthNeeded); tokenPtr = &parsePtr->tokenPtr[wordIndex]; } parsePtr->numTokens = wordIndex + 2*elemCount; /* * Generate a TCL_TOKEN_SIMPLE_WORD token sequence for * each element of the literal list we are expanding in * place. Take care with the start and size fields of each * token so they point to the right literal characters in * the original script to represent the right expanded * word value. */ nextElem = tokenPtr[1].start; while (isspace(UCHAR(*nextElem))) { nextElem++; } while (nextElem < listEnd) { tokenPtr->type = TCL_TOKEN_SIMPLE_WORD; tokenPtr->numComponents = 1; tokenPtr->start = nextElem; tokenPtr++; tokenPtr->type = TCL_TOKEN_TEXT; tokenPtr->numComponents = 0; TclFindElement(NULL, nextElem, listEnd - nextElem, &(tokenPtr->start), &nextElem, &(tokenPtr->size), NULL); if (tokenPtr->start + tokenPtr->size == listEnd) { tokenPtr[-1].size = listEnd - tokenPtr[-1].start; } else { tokenPtr[-1].size = tokenPtr->start + tokenPtr->size - tokenPtr[-1].start; tokenPtr[-1].size += (isspace(UCHAR( tokenPtr->start[tokenPtr->size])) == 0); } tokenPtr++; } } } else { /* * The word to be expanded is not a literal, so defer * expansion to compile/eval time by marking with a * TCL_TOKEN_EXPAND_WORD token. */ tokenPtr->type = TCL_TOKEN_EXPAND_WORD; } } else if ((tokenPtr->numComponents == 1) && (tokenPtr[1].type == TCL_TOKEN_TEXT)) { tokenPtr->type = TCL_TOKEN_SIMPLE_WORD; } /* * Do two additional checks: (a) make sure we're really at the end of * a word (there might have been garbage left after a quoted or braced * word), and (b) check for the end of the command. */ scanned = ParseWhiteSpace(src,numBytes, &parsePtr->incomplete, &type); if (scanned) { src += scanned; numBytes -= scanned; continue; } if (numBytes == 0) { parsePtr->term = src; break; } if ((type & terminators) != 0) { parsePtr->term = src; src++; break; } if (src[-1] == '"') { if (interp != NULL) { Tcl_SetResult(interp, "extra characters after close-quote", TCL_STATIC); } parsePtr->errorType = TCL_PARSE_QUOTE_EXTRA; } else { if (interp != NULL) { Tcl_SetResult(interp, "extra characters after close-brace", TCL_STATIC); } parsePtr->errorType = TCL_PARSE_BRACE_EXTRA; } parsePtr->term = src; goto error; } parsePtr->commandSize = src - parsePtr->commandStart; return TCL_OK; error: Tcl_FreeParse(parsePtr); parsePtr->commandSize = parsePtr->end - parsePtr->commandStart; return TCL_ERROR; } /* *---------------------------------------------------------------------- * * ParseWhiteSpace -- * * Scans up to numBytes bytes starting at src, consuming white space * between words as defined by Tcl's parsing rules. * * Results: * Returns the number of bytes recognized as white space. Records at * parsePtr, information about the parse. Records at typePtr the * character type of the non-whitespace character that terminated the * scan. * * Side effects: * None. * *---------------------------------------------------------------------- */ static int ParseWhiteSpace( const char *src, /* First character to parse. */ register int numBytes, /* Max number of bytes to scan. */ int *incompletePtr, /* Set this boolean memory to true if parsing * indicates an incomplete command. */ char *typePtr) /* Points to location to store character type * of character that ends run of whitespace */ { register char type = TYPE_NORMAL; register const char *p = src; while (1) { while (numBytes && ((type = CHAR_TYPE(*p)) & TYPE_SPACE)) { numBytes--; p++; } if (numBytes && (type & TYPE_SUBS)) { if (*p != '\\') { break; } if (--numBytes == 0) { break; } if (p[1] != '\n') { break; } p+=2; if (--numBytes == 0) { *incompletePtr = 1; break; } continue; } break; } *typePtr = type; return (p - src); } /* *---------------------------------------------------------------------- * * TclParseAllWhiteSpace -- * * Scans up to numBytes bytes starting at src, consuming all white space * including the command-terminating newline characters. * * Results: * Returns the number of bytes recognized as white space. * *---------------------------------------------------------------------- */ int TclParseAllWhiteSpace( const char *src, /* First character to parse. */ int numBytes) /* Max number of byes to scan */ { int dummy; char type; const char *p = src; do { int scanned = ParseWhiteSpace(p, numBytes, &dummy, &type); p += scanned; numBytes -= scanned; } while (numBytes && (*p == '\n') && (p++, --numBytes)); return (p-src); } /* *---------------------------------------------------------------------- * * TclParseHex -- * * Scans a hexadecimal number as a Tcl_UniChar value (e.g., for parsing * \x and \u escape sequences). At most numBytes bytes are scanned. * * Results: * The numeric value is stored in *resultPtr. Returns the number of bytes * consumed. * * Notes: * Relies on the following properties of the ASCII character set, with * which UTF-8 is compatible: * * The digits '0' .. '9' and the letters 'A' .. 'Z' and 'a' .. 'z' occupy * consecutive code points, and '0' < 'A' < 'a'. * *---------------------------------------------------------------------- */ int TclParseHex( const char *src, /* First character to parse. */ int numBytes, /* Max number of byes to scan */ Tcl_UniChar *resultPtr) /* Points to storage provided by caller where * the Tcl_UniChar resulting from the * conversion is to be written. */ { Tcl_UniChar result = 0; register const char *p = src; while (numBytes--) { unsigned char digit = UCHAR(*p); if (!isxdigit(digit)) { break; } ++p; result <<= 4; if (digit >= 'a') { result |= (10 + digit - 'a'); } else if (digit >= 'A') { result |= (10 + digit - 'A'); } else { result |= (digit - '0'); } } *resultPtr = result; return (p - src); } /* *---------------------------------------------------------------------- * * TclParseBackslash -- * * Scans up to numBytes bytes starting at src, consuming a backslash * sequence as defined by Tcl's parsing rules. * * Results: * Records at readPtr the number of bytes making up the backslash * sequence. Records at dst the UTF-8 encoded equivalent of that * backslash sequence. Returns the number of bytes written to dst, at * most TCL_UTF_MAX. Either readPtr or dst may be NULL, if the results * are not needed, but the return value is the same either way. * * Side effects: * None. * *---------------------------------------------------------------------- */ int TclParseBackslash( const char *src, /* Points to the backslash character of a a * backslash sequence. */ int numBytes, /* Max number of bytes to scan. */ int *readPtr, /* NULL, or points to storage where the number * of bytes scanned should be written. */ char *dst) /* NULL, or points to buffer where the UTF-8 * encoding of the backslash sequence is to be * written. At most TCL_UTF_MAX bytes will be * written there. */ { register const char *p = src+1; Tcl_UniChar result; int count; char buf[TCL_UTF_MAX]; if (numBytes == 0) { if (readPtr != NULL) { *readPtr = 0; } return 0; } if (dst == NULL) { dst = buf; } if (numBytes == 1) { /* * Can only scan the backslash, so return it. */ result = '\\'; count = 1; goto done; } count = 2; switch (*p) { /* * Note: in the conversions below, use absolute values (e.g., 0xa) * rather than symbolic values (e.g. \n) that get converted by the * compiler. It's possible that compilers on some platforms will do * the symbolic conversions differently, which could result in * non-portable Tcl scripts. */ case 'a': result = 0x7; break; case 'b': result = 0x8; break; case 'f': result = 0xc; break; case 'n': result = 0xa; break; case 'r': result = 0xd; break; case 't': result = 0x9; break; case 'v': result = 0xb; break; case 'x': count += TclParseHex(p+1, numBytes-1, &result); if (count == 2) { /* * No hexadigits -> This is just "x". */ result = 'x'; } else { /* * Keep only the last byte (2 hex digits). */ result = (unsigned char) result; } break; case 'u': count += TclParseHex(p+1, (numBytes > 5) ? 4 : numBytes-1, &result); if (count == 2) { /* * No hexadigits -> This is just "u". */ result = 'u'; } break; case '\n': count--; do { p++; count++; } while ((count < numBytes) && ((*p == ' ') || (*p == '\t'))); result = ' '; break; case 0: result = '\\'; count = 1; break; default: /* * Check for an octal number \oo?o? */ if (isdigit(UCHAR(*p)) && (UCHAR(*p) < '8')) { /* INTL: digit */ result = UCHAR(*p - '0'); p++; if ((numBytes == 2) || !isdigit(UCHAR(*p)) /* INTL: digit */ || (UCHAR(*p) >= '8')) { break; } count = 3; result = UCHAR((result << 3) + (*p - '0')); p++; if ((numBytes == 3) || !isdigit(UCHAR(*p)) /* INTL: digit */ || (UCHAR(*p) >= '8')) { break; } count = 4; result = UCHAR((result << 3) + (*p - '0')); break; } /* * We have to convert here in case the user has put a backslash in * front of a multi-byte utf-8 character. While this means nothing * special, we shouldn't break up a correct utf-8 character. [Bug * #217987] test subst-3.2 */ if (Tcl_UtfCharComplete(p, numBytes - 1)) { count = Tcl_UtfToUniChar(p, &result) + 1; /* +1 for '\' */ } else { char utfBytes[TCL_UTF_MAX]; memcpy(utfBytes, p, (size_t) (numBytes - 1)); utfBytes[numBytes - 1] = '\0'; count = Tcl_UtfToUniChar(utfBytes, &result) + 1; } break; } done: if (readPtr != NULL) { *readPtr = count; } return Tcl_UniCharToUtf((int) result, dst); } /* *---------------------------------------------------------------------- * * ParseComment -- * * Scans up to numBytes bytes starting at src, consuming a Tcl comment as * defined by Tcl's parsing rules. * * Results: * Records in parsePtr information about the parse. Returns the number of * bytes consumed. * * Side effects: * None. * *---------------------------------------------------------------------- */ static int ParseComment( const char *src, /* First character to parse. */ register int numBytes, /* Max number of bytes to scan. */ Tcl_Parse *parsePtr) /* Information about parse in progress. * Updated if parsing indicates an incomplete * command. */ { register const char *p = src; while (numBytes) { char type; int scanned; do { scanned = ParseWhiteSpace(p, numBytes, &parsePtr->incomplete, &type); p += scanned; numBytes -= scanned; } while (numBytes && (*p == '\n') && (p++,numBytes--)); if ((numBytes == 0) || (*p != '#')) { break; } if (parsePtr->commentStart == NULL) { parsePtr->commentStart = p; } while (numBytes) { if (*p == '\\') { scanned = ParseWhiteSpace(p, numBytes, &parsePtr->incomplete, &type); if (scanned) { p += scanned; numBytes -= scanned; } else { /* * General backslash substitution in comments isn't part * of the formal spec, but test parse-15.47 and history * indicate that it has been the de facto rule. Don't * change it now. */ TclParseBackslash(p, numBytes, &scanned, NULL); p += scanned; numBytes -= scanned; } } else { p++; numBytes--; if (p[-1] == '\n') { break; } } } parsePtr->commentSize = p - parsePtr->commentStart; } return (p - src); } /* *---------------------------------------------------------------------- * * ParseTokens -- * * This function forms the heart of the Tcl parser. It parses one or more * tokens from a string, up to a termination point specified by the * caller. This function is used to parse unquoted command words (those * not in quotes or braces), words in quotes, and array indices for * variables. No more than numBytes bytes will be scanned. * * Results: * Tokens are added to parsePtr and parsePtr->term is filled in with the * address of the character that terminated the parse (the first one * whose CHAR_TYPE matched mask or the character at parsePtr->end). The * return value is TCL_OK if the parse completed successfully and * TCL_ERROR otherwise. If a parse error occurs and parsePtr->interp is * not NULL, then an error message is left in the interpreter's result. * * Side effects: * None. * *---------------------------------------------------------------------- */ static int ParseTokens( register const char *src, /* First character to parse. */ register int numBytes, /* Max number of bytes to scan. */ int mask, /* Specifies when to stop parsing. The parse * stops at the first unquoted character whose * CHAR_TYPE contains any of the bits in * mask. */ int flags, /* OR-ed bits indicating what substitutions to * perform: TCL_SUBST_COMMANDS, * TCL_SUBST_VARIABLES, and * TCL_SUBST_BACKSLASHES */ Tcl_Parse *parsePtr) /* Information about parse in progress. * Updated with additional tokens and * termination information. */ { char type; int originalTokens; int noSubstCmds = !(flags & TCL_SUBST_COMMANDS); int noSubstVars = !(flags & TCL_SUBST_VARIABLES); int noSubstBS = !(flags & TCL_SUBST_BACKSLASHES); Tcl_Token *tokenPtr; /* * Each iteration through the following loop adds one token of type * TCL_TOKEN_TEXT, TCL_TOKEN_BS, TCL_TOKEN_COMMAND, or TCL_TOKEN_VARIABLE * to parsePtr. For TCL_TOKEN_VARIABLE tokens, additional tokens are added * for the parsed variable name. */ originalTokens = parsePtr->numTokens; while (numBytes && !((type = CHAR_TYPE(*src)) & mask)) { TclGrowParseTokenArray(parsePtr, 1); tokenPtr = &parsePtr->tokenPtr[parsePtr->numTokens]; tokenPtr->start = src; tokenPtr->numComponents = 0; if ((type & TYPE_SUBS) == 0) { /* * This is a simple range of characters. Scan to find the end of * the range. */ while ((++src, --numBytes) && !(CHAR_TYPE(*src) & (mask | TYPE_SUBS))) { /* empty loop */ } tokenPtr->type = TCL_TOKEN_TEXT; tokenPtr->size = src - tokenPtr->start; parsePtr->numTokens++; } else if (*src == '$') { int varToken; if (noSubstVars) { tokenPtr->type = TCL_TOKEN_TEXT; tokenPtr->size = 1; parsePtr->numTokens++; src++; numBytes--; continue; } /* * This is a variable reference. Call Tcl_ParseVarName to do all * the dirty work of parsing the name. */ varToken = parsePtr->numTokens; if (Tcl_ParseVarName(parsePtr->interp, src, numBytes, parsePtr, 1) != TCL_OK) { return TCL_ERROR; } src += parsePtr->tokenPtr[varToken].size; numBytes -= parsePtr->tokenPtr[varToken].size; } else if (*src == '[') { Tcl_Parse *nestedPtr; if (noSubstCmds) { tokenPtr->type = TCL_TOKEN_TEXT; tokenPtr->size = 1; parsePtr->numTokens++; src++; numBytes--; continue; } /* * Command substitution. Call Tcl_ParseCommand recursively (and * repeatedly) to parse the nested command(s), then throw away the * parse information. */ src++; numBytes--; nestedPtr = (Tcl_Parse *) TclStackAlloc(parsePtr->interp, sizeof(Tcl_Parse)); while (1) { if (Tcl_ParseCommand(parsePtr->interp, src, numBytes, 1, nestedPtr) != TCL_OK) { parsePtr->errorType = nestedPtr->errorType; parsePtr->term = nestedPtr->term; parsePtr->incomplete = nestedPtr->incomplete; TclStackFree(parsePtr->interp, nestedPtr); return TCL_ERROR; } src = nestedPtr->commandStart + nestedPtr->commandSize; numBytes = parsePtr->end - src; Tcl_FreeParse(nestedPtr); /* * Check for the closing ']' that ends the command * substitution. It must have been the last character of the * parsed command. */ if ((nestedPtr->term < parsePtr->end) && (*(nestedPtr->term) == ']') && !(nestedPtr->incomplete)) { break; } if (numBytes == 0) { if (parsePtr->interp != NULL) { Tcl_SetResult(parsePtr->interp, "missing close-bracket", TCL_STATIC); } parsePtr->errorType = TCL_PARSE_MISSING_BRACKET; parsePtr->term = tokenPtr->start; parsePtr->incomplete = 1; TclStackFree(parsePtr->interp, nestedPtr); return TCL_ERROR; } } TclStackFree(parsePtr->interp, nestedPtr); tokenPtr->type = TCL_TOKEN_COMMAND; tokenPtr->size = src - tokenPtr->start; parsePtr->numTokens++; } else if (*src == '\\') { if (noSubstBS) { tokenPtr->type = TCL_TOKEN_TEXT; tokenPtr->size = 1; parsePtr->numTokens++; src++; numBytes--; continue; } /* * Backslash substitution. */ TclParseBackslash(src, numBytes, &tokenPtr->size, NULL); if (tokenPtr->size == 1) { /* * Just a backslash, due to end of string. */ tokenPtr->type = TCL_TOKEN_TEXT; parsePtr->numTokens++; src++; numBytes--; continue; } if (src[1] == '\n') { if (numBytes == 2) { parsePtr->incomplete = 1; } /* * Note: backslash-newline is special in that it is treated * the same as a space character would be. This means that it * could terminate the token. */ if (mask & TYPE_SPACE) { if (parsePtr->numTokens == originalTokens) { goto finishToken; } break; } } tokenPtr->type = TCL_TOKEN_BS; parsePtr->numTokens++; src += tokenPtr->size; numBytes -= tokenPtr->size; } else if (*src == 0) { tokenPtr->type = TCL_TOKEN_TEXT; tokenPtr->size = 1; parsePtr->numTokens++; src++; numBytes--; } else { Tcl_Panic("ParseTokens encountered unknown character"); } } if (parsePtr->numTokens == originalTokens) { /* * There was nothing in this range of text. Add an empty token for the * empty range, so that there is always at least one token added. */ TclGrowParseTokenArray(parsePtr, 1); tokenPtr = &parsePtr->tokenPtr[parsePtr->numTokens]; tokenPtr->start = src; tokenPtr->numComponents = 0; finishToken: tokenPtr->type = TCL_TOKEN_TEXT; tokenPtr->size = 0; parsePtr->numTokens++; } parsePtr->term = src; return TCL_OK; } /* *---------------------------------------------------------------------- * * Tcl_FreeParse -- * * This function is invoked to free any dynamic storage that may have * been allocated by a previous call to Tcl_ParseCommand. * * Results: * None. * * Side effects: * If there is any dynamically allocated memory in *parsePtr, it is * freed. * *---------------------------------------------------------------------- */ void Tcl_FreeParse( Tcl_Parse *parsePtr) /* Structure that was filled in by a previous * call to Tcl_ParseCommand. */ { if (parsePtr->tokenPtr != parsePtr->staticTokens) { ckfree((char *) parsePtr->tokenPtr); parsePtr->tokenPtr = parsePtr->staticTokens; } } /* *---------------------------------------------------------------------- * * Tcl_ParseVarName -- * * Given a string starting with a $ sign, parse off a variable name and * return information about the parse. No more than numBytes bytes will * be scanned. * * Results: * The return value is TCL_OK if the command was parsed successfully and * TCL_ERROR otherwise. If an error occurs and interp isn't NULL then an * error message is left in its result. On a successful return, tokenPtr * and numTokens fields of parsePtr are filled in with information about * the variable name that was parsed. The "size" field of the first new * token gives the total number of bytes in the variable name. Other * fields in parsePtr are undefined. * * Side effects: * If there is insufficient space in parsePtr to hold all the information * about the command, then additional space is malloc-ed. If the function * returns TCL_OK then the caller must eventually invoke Tcl_FreeParse to * release any additional space that was allocated. * *---------------------------------------------------------------------- */ int Tcl_ParseVarName( Tcl_Interp *interp, /* Interpreter to use for error reporting; if * NULL, then no error message is provided. */ const char *start, /* Start of variable substitution string. * First character must be "$". */ register int numBytes, /* Total number of bytes in string. If < 0, * the string consists of all bytes up to the * first null character. */ Tcl_Parse *parsePtr, /* Structure to fill in with information about * the variable name. */ int append) /* Non-zero means append tokens to existing * information in parsePtr; zero means ignore * existing tokens in parsePtr and * reinitialize it. */ { Tcl_Token *tokenPtr; register const char *src; unsigned char c; int varIndex, offset; Tcl_UniChar ch; unsigned array; if ((numBytes == 0) || (start == NULL)) { return TCL_ERROR; } if (numBytes < 0) { numBytes = strlen(start); } if (!append) { TclParseInit(interp, start, numBytes, parsePtr); } /* * Generate one token for the variable, an additional token for the name, * plus any number of additional tokens for the index, if there is one. */ src = start; TclGrowParseTokenArray(parsePtr, 2); tokenPtr = &parsePtr->tokenPtr[parsePtr->numTokens]; tokenPtr->type = TCL_TOKEN_VARIABLE; tokenPtr->start = src; varIndex = parsePtr->numTokens; parsePtr->numTokens++; tokenPtr++; src++; numBytes--; if (numBytes == 0) { goto justADollarSign; } tokenPtr->type = TCL_TOKEN_TEXT; tokenPtr->start = src; tokenPtr->numComponents = 0; /* * The name of the variable can have three forms: * 1. The $ sign is followed by an open curly brace. Then the variable * name is everything up to the next close curly brace, and the * variable is a scalar variable. * 2. The $ sign is not followed by an open curly brace. Then the variable * name is everything up to the next character that isn't a letter, * digit, or underscore. :: sequences are also considered part of the * variable name, in order to support namespaces. If the following * character is an open parenthesis, then the information between * parentheses is the array element name. * 3. The $ sign is followed by something that isn't a letter, digit, or * underscore: in this case, there is no variable name and the token is * just "$". */ if (*src == '{') { src++; numBytes--; tokenPtr->type = TCL_TOKEN_TEXT; tokenPtr->start = src; tokenPtr->numComponents = 0; while (numBytes && (*src != '}')) { numBytes--; src++; } if (numBytes == 0) { if (parsePtr->interp != NULL) { Tcl_SetResult(parsePtr->interp, "missing close-brace for variable name", TCL_STATIC); } parsePtr->errorType = TCL_PARSE_MISSING_VAR_BRACE; parsePtr->term = tokenPtr->start-1; parsePtr->incomplete = 1; goto error; } tokenPtr->size = src - tokenPtr->start; tokenPtr[-1].size = src - tokenPtr[-1].start; parsePtr->numTokens++; src++; } else { tokenPtr->type = TCL_TOKEN_TEXT; tokenPtr->start = src; tokenPtr->numComponents = 0; while (numBytes) { if (Tcl_UtfCharComplete(src, numBytes)) { offset = Tcl_UtfToUniChar(src, &ch); } else { char utfBytes[TCL_UTF_MAX]; memcpy(utfBytes, src, (size_t) numBytes); utfBytes[numBytes] = '\0'; offset = Tcl_UtfToUniChar(utfBytes, &ch); } c = UCHAR(ch); if (isalnum(c) || (c == '_')) { /* INTL: ISO only, UCHAR. */ src += offset; numBytes -= offset; continue; } if ((c == ':') && (numBytes != 1) && (src[1] == ':')) { src += 2; numBytes -= 2; while (numBytes && (*src == ':')) { src++; numBytes--; } continue; } break; } /* * Support for empty array names here. */ array = (numBytes && (*src == '(')); tokenPtr->size = src - tokenPtr->start; if ((tokenPtr->size == 0) && !array) { goto justADollarSign; } parsePtr->numTokens++; if (array) { /* * This is a reference to an array element. Call ParseTokens * recursively to parse the element name, since it could contain * any number of substitutions. */ if (TCL_OK != ParseTokens(src+1, numBytes-1, TYPE_CLOSE_PAREN, TCL_SUBST_ALL, parsePtr)) { goto error; } if ((parsePtr->term == src+numBytes) || (*parsePtr->term != ')')){ if (parsePtr->interp != NULL) { Tcl_SetResult(parsePtr->interp, "missing )", TCL_STATIC); } parsePtr->errorType = TCL_PARSE_MISSING_PAREN; parsePtr->term = src; parsePtr->incomplete = 1; goto error; } src = parsePtr->term + 1; } } tokenPtr = &parsePtr->tokenPtr[varIndex]; tokenPtr->size = src - tokenPtr->start; tokenPtr->numComponents = parsePtr->numTokens - (varIndex + 1); return TCL_OK; /* * The dollar sign isn't followed by a variable name. Replace the * TCL_TOKEN_VARIABLE token with a TCL_TOKEN_TEXT token for the dollar * sign. */ justADollarSign: tokenPtr = &parsePtr->tokenPtr[varIndex]; tokenPtr->type = TCL_TOKEN_TEXT; tokenPtr->size = 1; tokenPtr->numComponents = 0; return TCL_OK; error: Tcl_FreeParse(parsePtr); return TCL_ERROR; } /* *---------------------------------------------------------------------- * * Tcl_ParseVar -- * * Given a string starting with a $ sign, parse off a variable name and * return its value. * * Results: * The return value is the contents of the variable given by the leading * characters of string. If termPtr isn't NULL, *termPtr gets filled in * with the address of the character just after the last one in the * variable specifier. If the variable doesn't exist, then the return * value is NULL and an error message will be left in interp's result. * * Side effects: * None. * *---------------------------------------------------------------------- */ const char * Tcl_ParseVar( Tcl_Interp *interp, /* Context for looking up variable. */ register const char *start, /* Start of variable substitution. First * character must be "$". */ const char **termPtr) /* If non-NULL, points to word to fill in with * character just after last one in the * variable specifier. */ { register Tcl_Obj *objPtr; int code; Tcl_Parse *parsePtr = (Tcl_Parse *) TclStackAlloc(interp, sizeof(Tcl_Parse)); if (Tcl_ParseVarName(interp, start, -1, parsePtr, 0) != TCL_OK) { TclStackFree(interp, parsePtr); return NULL; } if (termPtr != NULL) { *termPtr = start + parsePtr->tokenPtr->size; } if (parsePtr->numTokens == 1) { /* * There isn't a variable name after all: the $ is just a $. */ TclStackFree(interp, parsePtr); return "$"; } code = TclSubstTokens(interp, parsePtr->tokenPtr, parsePtr->numTokens, NULL, 1, NULL, NULL); TclStackFree(interp, parsePtr); if (code != TCL_OK) { return NULL; } objPtr = Tcl_GetObjResult(interp); /* * At this point we should have an object containing the value of a * variable. Just return the string from that object. * * This should have returned the object for the user to manage, but * instead we have some weak reference to the string value in the object, * which is why we make sure the object exists after resetting the result. * This isn't ideal, but it's the best we can do with the current * documented interface. -- hobbs */ if (!Tcl_IsShared(objPtr)) { Tcl_IncrRefCount(objPtr); } Tcl_ResetResult(interp); return TclGetString(objPtr); } /* *---------------------------------------------------------------------- * * Tcl_ParseBraces -- * * Given a string in braces such as a Tcl command argument or a string * value in a Tcl expression, this function parses the string and returns * information about the parse. No more than numBytes bytes will be * scanned. * * Results: * The return value is TCL_OK if the string was parsed successfully and * TCL_ERROR otherwise. If an error occurs and interp isn't NULL then an * error message is left in its result. On a successful return, tokenPtr * and numTokens fields of parsePtr are filled in with information about * the string that was parsed. Other fields in parsePtr are undefined. * termPtr is set to point to the character just after the last one in * the braced string. * * Side effects: * If there is insufficient space in parsePtr to hold all the information * about the command, then additional space is malloc-ed. If the function * returns TCL_OK then the caller must eventually invoke Tcl_FreeParse to * release any additional space that was allocated. * *---------------------------------------------------------------------- */ int Tcl_ParseBraces( Tcl_Interp *interp, /* Interpreter to use for error reporting; if * NULL, then no error message is provided. */ const char *start, /* Start of string enclosed in braces. The * first character must be {'. */ register int numBytes, /* Total number of bytes in string. If < 0, * the string consists of all bytes up to the * first null character. */ register Tcl_Parse *parsePtr, /* Structure to fill in with information about * the string. */ int append, /* Non-zero means append tokens to existing * information in parsePtr; zero means ignore * existing tokens in parsePtr and * reinitialize it. */ const char **termPtr) /* If non-NULL, points to word in which to * store a pointer to the character just after * the terminating '}' if the parse was * successful. */ { Tcl_Token *tokenPtr; register const char *src; int startIndex, level, length; if ((numBytes == 0) || (start == NULL)) { return TCL_ERROR; } if (numBytes < 0) { numBytes = strlen(start); } if (!append) { TclParseInit(interp, start, numBytes, parsePtr); } src = start; startIndex = parsePtr->numTokens; TclGrowParseTokenArray(parsePtr, 1); tokenPtr = &parsePtr->tokenPtr[startIndex]; tokenPtr->type = TCL_TOKEN_TEXT; tokenPtr->start = src+1; tokenPtr->numComponents = 0; level = 1; while (1) { while (++src, --numBytes) { if (CHAR_TYPE(*src) != TYPE_NORMAL) { break; } } if (numBytes == 0) { goto missingBraceError; } switch (*src) { case '{': level++; break; case '}': if (--level == 0) { /* * Decide if we need to finish emitting a partially-finished * token. There are 3 cases: * {abc \newline xyz} or {xyz} * - finish emitting "xyz" token * {abc \newline} * - don't emit token after \newline * {} - finish emitting zero-sized token * * The last case ensures that there is a token (even if empty) * that describes the braced string. */ if ((src != tokenPtr->start) || (parsePtr->numTokens == startIndex)) { tokenPtr->size = (src - tokenPtr->start); parsePtr->numTokens++; } if (termPtr != NULL) { *termPtr = src+1; } return TCL_OK; } break; case '\\': TclParseBackslash(src, numBytes, &length, NULL); if ((length > 1) && (src[1] == '\n')) { /* * A backslash-newline sequence must be collapsed, even inside * braces, so we have to split the word into multiple tokens * so that the backslash-newline can be represented * explicitly. */ if (numBytes == 2) { parsePtr->incomplete = 1; } tokenPtr->size = (src - tokenPtr->start); if (tokenPtr->size != 0) { parsePtr->numTokens++; } TclGrowParseTokenArray(parsePtr, 2); tokenPtr = &parsePtr->tokenPtr[parsePtr->numTokens]; tokenPtr->type = TCL_TOKEN_BS; tokenPtr->start = src; tokenPtr->size = length; tokenPtr->numComponents = 0; parsePtr->numTokens++; src += length - 1; numBytes -= length - 1; tokenPtr++; tokenPtr->type = TCL_TOKEN_TEXT; tokenPtr->start = src + 1; tokenPtr->numComponents = 0; } else { src += length - 1; numBytes -= length - 1; } break; } } missingBraceError: parsePtr->errorType = TCL_PARSE_MISSING_BRACE; parsePtr->term = start; parsePtr->incomplete = 1; if (parsePtr->interp == NULL) { /* * Skip straight to the exit code since we have no interpreter to put * error message in. */ goto error; } Tcl_SetResult(parsePtr->interp, "missing close-brace", TCL_STATIC); /* * Guess if the problem is due to comments by searching the source string * for a possible open brace within the context of a comment. Since we * aren't performing a full Tcl parse, just look for an open brace * preceded by a '#' on the same line. */ { register int openBrace = 0; while (--src > start) { switch (*src) { case '{': openBrace = 1; break; case '\n': openBrace = 0; break; case '#' : if (openBrace && isspace(UCHAR(src[-1]))) { Tcl_AppendResult(parsePtr->interp, ": possible unbalanced brace in comment", NULL); goto error; } break; } } } error: Tcl_FreeParse(parsePtr); return TCL_ERROR; } /* *---------------------------------------------------------------------- * * Tcl_ParseQuotedString -- * * Given a double-quoted string such as a quoted Tcl command argument or * a quoted value in a Tcl expression, this function parses the string * and returns information about the parse. No more than numBytes bytes * will be scanned. * * Results: * The return value is TCL_OK if the string was parsed successfully and * TCL_ERROR otherwise. If an error occurs and interp isn't NULL then an * error message is left in its result. On a successful return, tokenPtr * and numTokens fields of parsePtr are filled in with information about * the string that was parsed. Other fields in parsePtr are undefined. * termPtr is set to point to the character just after the quoted * string's terminating close-quote. * * Side effects: * If there is insufficient space in parsePtr to hold all the information * about the command, then additional space is malloc-ed. If the function * returns TCL_OK then the caller must eventually invoke Tcl_FreeParse to * release any additional space that was allocated. * *---------------------------------------------------------------------- */ int Tcl_ParseQuotedString( Tcl_Interp *interp, /* Interpreter to use for error reporting; if * NULL, then no error message is provided. */ const char *start, /* Start of the quoted string. The first * character must be '"'. */ register int numBytes, /* Total number of bytes in string. If < 0, * the string consists of all bytes up to the * first null character. */ register Tcl_Parse *parsePtr, /* Structure to fill in with information about * the string. */ int append, /* Non-zero means append tokens to existing * information in parsePtr; zero means ignore * existing tokens in parsePtr and * reinitialize it. */ const char **termPtr) /* If non-NULL, points to word in which to * store a pointer to the character just after * the quoted string's terminating close-quote * if the parse succeeds. */ { if ((numBytes == 0) || (start == NULL)) { return TCL_ERROR; } if (numBytes < 0) { numBytes = strlen(start); } if (!append) { TclParseInit(interp, start, numBytes, parsePtr); } if (TCL_OK != ParseTokens(start+1, numBytes-1, TYPE_QUOTE, TCL_SUBST_ALL, parsePtr)) { goto error; } if (*parsePtr->term != '"') { if (parsePtr->interp != NULL) { Tcl_SetResult(parsePtr->interp, "missing \"", TCL_STATIC); } parsePtr->errorType = TCL_PARSE_MISSING_QUOTE; parsePtr->term = start; parsePtr->incomplete = 1; goto error; } if (termPtr != NULL) { *termPtr = (parsePtr->term + 1); } return TCL_OK; error: Tcl_FreeParse(parsePtr); return TCL_ERROR; } /* *---------------------------------------------------------------------- * * Tcl_SubstObj -- * * This function performs the substitutions specified on the given string * as described in the user documentation for the "subst" Tcl command. * * Results: * A Tcl_Obj* containing the substituted string, or NULL to indicate that * an error occurred. * * Side effects: * See the user documentation. * *---------------------------------------------------------------------- */ Tcl_Obj * Tcl_SubstObj( Tcl_Interp *interp, /* Interpreter in which substitution occurs */ Tcl_Obj *objPtr, /* The value to be substituted. */ int flags) /* What substitutions to do. */ { int length, tokensLeft, code; Tcl_Token *endTokenPtr; Tcl_Obj *result, *errMsg = NULL; const char *p = TclGetStringFromObj(objPtr, &length); Tcl_Parse *parsePtr = (Tcl_Parse *) TclStackAlloc(interp, sizeof(Tcl_Parse)); TclParseInit(interp, p, length, parsePtr); /* * First parse the string rep of objPtr, as if it were enclosed as a * "-quoted word in a normal Tcl command. Honor flags that selectively * inhibit types of substitution. */ if (TCL_OK != ParseTokens(p, length, /* mask */ 0, flags, parsePtr)) { /* * There was a parse error. Save the error message for possible * reporting later. */ errMsg = Tcl_GetObjResult(interp); Tcl_IncrRefCount(errMsg); /* * We need to re-parse to get the portion of the string we can [subst] * before the parse error. Sadly, all the Tcl_Token's created by the * first parse attempt are gone, freed according to the public spec * for the Tcl_Parse* routines. The only clue we have is parse.term, * which points to either the unmatched opener, or to characters that * follow a close brace or close quote. * * Call ParseTokens again, working on the string up to parse.term. * Keep repeating until we get a good parse on a prefix. */ do { parsePtr->numTokens = 0; parsePtr->tokensAvailable = NUM_STATIC_TOKENS; parsePtr->end = parsePtr->term; parsePtr->incomplete = 0; parsePtr->errorType = TCL_PARSE_SUCCESS; } while (TCL_OK != ParseTokens(p, parsePtr->end - p, 0, flags, parsePtr)); /* * The good parse will have to be followed by {, (, or [. */ switch (*(parsePtr->term)) { case '{': /* * Parse error was a missing } in a ${varname} variable * substitution at the toplevel. We will subst everything up to * that broken variable substitution before reporting the parse * error. Substituting the leftover '$' will have no side-effects, * so the current token stream is fine. */ break; case '(': /* * Parse error was during the parsing of the index part of an * array variable substitution at the toplevel. */ if (*(parsePtr->term - 1) == '$') { /* * Special case where removing the array index left us with * just a dollar sign (array variable with name the empty * string as its name), instead of with a scalar variable * reference. * * As in the previous case, existing token stream is OK. */ } else { /* * The current parse includes a successful parse of a scalar * variable substitution where there should have been an array * variable substitution. We remove that mistaken part of the * parse before moving on. A scalar variable substitution is * two tokens. */ Tcl_Token *varTokenPtr = parsePtr->tokenPtr + parsePtr->numTokens - 2; if (varTokenPtr->type != TCL_TOKEN_VARIABLE) { Tcl_Panic("Tcl_SubstObj: programming error"); } if (varTokenPtr[1].type != TCL_TOKEN_TEXT) { Tcl_Panic("Tcl_SubstObj: programming error"); } parsePtr->numTokens -= 2; } break; case '[': /* * Parse error occurred during parsing of a toplevel command * substitution. */ parsePtr->end = p + length; p = parsePtr->term + 1; length = parsePtr->end - p; if (length == 0) { /* * No commands, just an unmatched [. As in previous cases, * existing token stream is OK. */ } else { /* * We want to add the parsing of as many commands as we can * within that substitution until we reach the actual parse * error. We'll do additional parsing to determine what length * to claim for the final TCL_TOKEN_COMMAND token. */ Tcl_Token *tokenPtr; const char *lastTerm = parsePtr->term; Tcl_Parse *nestedPtr = (Tcl_Parse *) TclStackAlloc(interp, sizeof(Tcl_Parse)); while (TCL_OK == Tcl_ParseCommand(NULL, p, length, 0, nestedPtr)) { Tcl_FreeParse(nestedPtr); p = nestedPtr->term + (nestedPtr->term < nestedPtr->end); length = nestedPtr->end - p; if ((length == 0) && (nestedPtr->term == nestedPtr->end)) { /* * If we run out of string, blame the missing close * bracket on the last command, and do not evaluate it * during substitution. */ break; } lastTerm = nestedPtr->term; } TclStackFree(interp, nestedPtr); if (lastTerm == parsePtr->term) { /* * Parse error in first command. No commands to subst, add * no more tokens. */ break; } /* * Create a command substitution token for whatever commands * got parsed. */ TclGrowParseTokenArray(parsePtr, 1); tokenPtr = &(parsePtr->tokenPtr[parsePtr->numTokens]); tokenPtr->start = parsePtr->term; tokenPtr->numComponents = 0; tokenPtr->type = TCL_TOKEN_COMMAND; tokenPtr->size = lastTerm - tokenPtr->start + 1; parsePtr->numTokens++; } break; default: Tcl_Panic("bad parse in Tcl_SubstObj: %c", p[length]); } } /* * Next, substitute the parsed tokens just as in normal Tcl evaluation. */ endTokenPtr = parsePtr->tokenPtr + parsePtr->numTokens; tokensLeft = parsePtr->numTokens; code = TclSubstTokens(interp, endTokenPtr - tokensLeft, tokensLeft, &tokensLeft, 1, NULL, NULL); if (code == TCL_OK) { Tcl_FreeParse(parsePtr); TclStackFree(interp, parsePtr); if (errMsg != NULL) { Tcl_SetObjResult(interp, errMsg); Tcl_DecrRefCount(errMsg); return NULL; } return Tcl_GetObjResult(interp); } result = Tcl_NewObj(); while (1) { switch (code) { case TCL_ERROR: Tcl_FreeParse(parsePtr); TclStackFree(interp, parsePtr); Tcl_DecrRefCount(result); if (errMsg != NULL) { Tcl_DecrRefCount(errMsg); } return NULL; case TCL_BREAK: tokensLeft = 0; /* Halt substitution */ default: Tcl_AppendObjToObj(result, Tcl_GetObjResult(interp)); } if (tokensLeft == 0) { Tcl_FreeParse(parsePtr); TclStackFree(interp, parsePtr); if (errMsg != NULL) { if (code != TCL_BREAK) { Tcl_DecrRefCount(result); Tcl_SetObjResult(interp, errMsg); Tcl_DecrRefCount(errMsg); return NULL; } Tcl_DecrRefCount(errMsg); } return result; } code = TclSubstTokens(interp, endTokenPtr - tokensLeft, tokensLeft, &tokensLeft, 1, NULL, NULL); } } /* *---------------------------------------------------------------------- * * TclSubstTokens -- * * Accepts an array of count Tcl_Token's, and creates a result value in * the interp from concatenating the results of performing Tcl * substitution on each Tcl_Token. Substitution is interrupted if any * non-TCL_OK completion code arises. * * Results: * The return value is a standard Tcl completion code. The result in * interp is the substituted value, or an error message if TCL_ERROR is * returned. If tokensLeftPtr is not NULL, then it points to an int where * the number of tokens remaining to be processed is written. * * Side effects: * Can be anything, depending on the types of substitution done. * *---------------------------------------------------------------------- */ int TclSubstTokens( Tcl_Interp *interp, /* Interpreter in which to lookup variables, * execute nested commands, and report * errors. */ Tcl_Token *tokenPtr, /* Pointer to first in an array of tokens to * evaluate and concatenate. */ int count, /* Number of tokens to consider at tokenPtr. * Must be at least 1. */ int *tokensLeftPtr, /* If not NULL, points to memory where an * integer representing the number of tokens * left to be substituted will be written */ int line, /* The line the script starts on. */ int* clNextOuter, /* Information about an outer context for */ CONST char* outerScript) /* continuation line data. This is set by * EvalEx() to properly handle [...]-nested * commands. The 'outerScript' refers to the * most-outer script containing the embedded * command, which is refered to by 'script'. The * 'clNextOuter' refers to the current entry in * the table of continuation lines in this * "master script", and the character offsets are * relative to the 'outerScript' as well. * * If outerScript == script, then this call is for * words in the outer-most script/command. See * Tcl_EvalEx() and TclEvalObjEx() for the places * generating arguments for which this is true. */ { Tcl_Obj *result; int code = TCL_OK; #define NUM_STATIC_POS 20 int isLiteral, maxNumCL, numCL, i, adjust; int* clPosition; Interp* iPtr = (Interp*) interp; int inFile = iPtr->evalFlags & TCL_EVAL_FILE; /* * Each pass through this loop will substitute one token, and its * components, if any. The only thing tricky here is that we go to some * effort to pass Tcl_Obj's through untouched, to avoid string copying and * Tcl_Obj creation if possible, to aid performance and limit shimmering. * * Further optimization opportunities might be to check for the equivalent * of Tcl_SetObjResult(interp, Tcl_GetObjResult(interp)) and omit them. */ /* * For the handling of continuation lines in literals we first check if * this is actually a literal. For if not we can forego the additional * processing. Otherwise we pre-allocate a small table to store the * locations of all continuation lines we find in this literal, if * any. The table is extended if needed. */ numCL = 0; maxNumCL = 0; isLiteral = 1; for (i=0 ; i < count; i++) { if ((tokenPtr[i].type != TCL_TOKEN_TEXT) && (tokenPtr[i].type != TCL_TOKEN_BS)) { isLiteral = 0; break; } } if (isLiteral) { maxNumCL = NUM_STATIC_POS; clPosition = (int*) ckalloc (maxNumCL*sizeof(int)); } adjust = 0; result = NULL; for (; count>0 && code==TCL_OK ; count--, tokenPtr++) { Tcl_Obj *appendObj = NULL; const char *append = NULL; int appendByteLength = 0; char utfCharBytes[TCL_UTF_MAX]; switch (tokenPtr->type) { case TCL_TOKEN_TEXT: append = tokenPtr->start; appendByteLength = tokenPtr->size; break; case TCL_TOKEN_BS: appendByteLength = Tcl_UtfBackslash(tokenPtr->start, NULL, utfCharBytes); append = utfCharBytes; /* * If the backslash sequence we found is in a literal, and * represented a continuation line, we compute and store its * location (as char offset to the beginning of the _result_ * script). We may have to extend the table of locations. * * Note that the continuation line information is relevant even if * the word we are processing is not a literal, as it can affect * nested commands. See the branch for TCL_TOKEN_COMMAND below, * where the adjustment we are tracking here is taken into * account. The good thing is that we do not need a table of * everything, just the number of lines we have to add as * correction. */ if ((appendByteLength == 1) && (utfCharBytes[0] == ' ') && (tokenPtr->start[1] == '\n')) { if (isLiteral) { int clPos; if (result == 0) { clPos = 0; } else { Tcl_GetStringFromObj(result, &clPos); } if (numCL >= maxNumCL) { maxNumCL *= 2; clPosition = (int*) ckrealloc ((char*)clPosition, maxNumCL*sizeof(int)); } clPosition[numCL] = clPos; numCL ++; } adjust ++; } break; case TCL_TOKEN_COMMAND: { /* TIP #280: Transfer line information to nested command */ iPtr->numLevels++; code = TclInterpReady(interp); if (code == TCL_OK) { /* * Test cases: info-30.{6,8,9} */ int theline; TclAdvanceContinuations (&line, &clNextOuter, tokenPtr->start - outerScript); theline = line + adjust; code = TclEvalEx(interp, tokenPtr->start+1, tokenPtr->size-2, 0, theline, clNextOuter, outerScript); /* * Restore flag reset by nested eval for future bracketed * commands and their cmdframe setup */ if (inFile) { iPtr->evalFlags |= TCL_EVAL_FILE; } } iPtr->numLevels--; TclResetCancellation(interp, 0); appendObj = Tcl_GetObjResult(interp); break; } case TCL_TOKEN_VARIABLE: { Tcl_Obj *arrayIndex = NULL; Tcl_Obj *varName = NULL; if (tokenPtr->numComponents > 1) { /* * Subst the index part of an array variable reference. */ code = TclSubstTokens(interp, tokenPtr+2, tokenPtr->numComponents - 1, NULL, line, NULL, NULL); arrayIndex = Tcl_GetObjResult(interp); Tcl_IncrRefCount(arrayIndex); } if (code == TCL_OK) { varName = Tcl_NewStringObj(tokenPtr[1].start, tokenPtr[1].size); appendObj = Tcl_ObjGetVar2(interp, varName, arrayIndex, TCL_LEAVE_ERR_MSG); Tcl_DecrRefCount(varName); if (appendObj == NULL) { code = TCL_ERROR; } } switch (code) { case TCL_OK: /* Got value */ case TCL_ERROR: /* Already have error message */ case TCL_BREAK: /* Will not substitute anyway */ case TCL_CONTINUE: /* Will not substitute anyway */ break; default: /* * All other return codes, we will subst the result from the * code-throwing evaluation. */ appendObj = Tcl_GetObjResult(interp); } if (arrayIndex != NULL) { Tcl_DecrRefCount(arrayIndex); } count -= tokenPtr->numComponents; tokenPtr += tokenPtr->numComponents; break; } default: Tcl_Panic("unexpected token type in TclSubstTokens: %d", tokenPtr->type); } if ((code == TCL_BREAK) || (code == TCL_CONTINUE)) { /* * Inhibit substitution. */ continue; } if (result == NULL) { /* * First pass through. If we have a Tcl_Obj, just use it. If not, * create one from our string. */ if (appendObj != NULL) { result = appendObj; } else { result = Tcl_NewStringObj(append, appendByteLength); } Tcl_IncrRefCount(result); } else { /* * Subsequent passes. Append to result. */ if (Tcl_IsShared(result)) { Tcl_DecrRefCount(result); result = Tcl_DuplicateObj(result); Tcl_IncrRefCount(result); } if (appendObj != NULL) { Tcl_AppendObjToObj(result, appendObj); } else { Tcl_AppendToObj(result, append, appendByteLength); } } } if (code != TCL_ERROR) { /* Keep error message in result! */ if (result != NULL) { Tcl_SetObjResult(interp, result); /* * If the code found continuation lines (which implies that this * word is a literal), then we store the accumulated table of * locations in the thread-global data structure for the bytecode * compiler to find later, assuming that the literal is a script * which will be compiled. */ if (numCL) { TclContinuationsEnter(result, numCL, clPosition); } /* * Release the temp table we used to collect the locations of * continuation lines, if any. */ if (maxNumCL) { ckfree ((char*) clPosition); } } else { Tcl_ResetResult(interp); } } if (tokensLeftPtr != NULL) { *tokensLeftPtr = count; } if (result != NULL) { Tcl_DecrRefCount(result); } return code; } /* *---------------------------------------------------------------------- * * CommandComplete -- * * This function is shared by TclCommandComplete and * Tcl_ObjCommandComplete; it does all the real work of seeing whether a * script is complete * * Results: * 1 is returned if the script is complete, 0 if there are open * delimiters such as " or (. 1 is also returned if there is a parse * error in the script other than unmatched delimiters. * * Side effects: * None. * *---------------------------------------------------------------------- */ static inline int CommandComplete( const char *script, /* Script to check. */ int numBytes) /* Number of bytes in script. */ { Tcl_Parse parse; const char *p, *end; int result; p = script; end = p + numBytes; while (Tcl_ParseCommand(NULL, p, end - p, 0, &parse) == TCL_OK) { p = parse.commandStart + parse.commandSize; if (p >= end) { break; } Tcl_FreeParse(&parse); } if (parse.incomplete) { result = 0; } else { result = 1; } Tcl_FreeParse(&parse); return result; } /* *---------------------------------------------------------------------- * * Tcl_CommandComplete -- * * Given a partial or complete Tcl script, this function determines * whether the script is complete in the sense of having matched braces * and quotes and brackets. * * Results: * 1 is returned if the script is complete, 0 otherwise. 1 is also * returned if there is a parse error in the script other than unmatched * delimiters. * * Side effects: * None. * *---------------------------------------------------------------------- */ int Tcl_CommandComplete( const char *script) /* Script to check. */ { return CommandComplete(script, (int) strlen(script)); } /* *---------------------------------------------------------------------- * * TclObjCommandComplete -- * * Given a partial or complete Tcl command in a Tcl object, this function * determines whether the command is complete in the sense of having * matched braces and quotes and brackets. * * Results: * 1 is returned if the command is complete, 0 otherwise. * * Side effects: * None. * *---------------------------------------------------------------------- */ int TclObjCommandComplete( Tcl_Obj *objPtr) /* Points to object holding script to * check. */ { int length; const char *script = Tcl_GetStringFromObj(objPtr, &length); return CommandComplete(script, length); } /* *---------------------------------------------------------------------- * * TclIsLocalScalar -- * * Check to see if a given string is a legal scalar variable name with no * namespace qualifiers or substitutions. * * Results: * Returns 1 if the variable is a local scalar. * * Side effects: * None. * *---------------------------------------------------------------------- */ int TclIsLocalScalar( const char *src, int len) { const char *p; const char *lastChar = src + (len - 1); for (p=src ; p<=lastChar ; p++) { if ((CHAR_TYPE(*p) != TYPE_NORMAL) && (CHAR_TYPE(*p) != TYPE_COMMAND_END)) { /* * TCL_COMMAND_END is returned for the last character of the * string. By this point we know it isn't an array or namespace * reference. */ return 0; } if (*p == '(') { if (*lastChar == ')') { /* We have an array element */ return 0; } } else if (*p == ':') { if ((p != lastChar) && *(p+1) == ':') { /* qualified name */ return 0; } } } return 1; } /* * Local Variables: * mode: c * c-basic-offset: 4 * fill-column: 78 * End: */