CMake/Source/cmRegularExpression.cxx

1280 lines
37 KiB
C++

//
// Copyright (C) 1991 Texas Instruments Incorporated.
//
// Permission is granted to any individual or institution to use, copy, modify,
// and distribute this software, provided that this complete copyright and
// permission notice is maintained, intact, in all copies and supporting
// documentation.
//
// Texas Instruments Incorporated provides this software "as is" without
// express or implied warranty.
//
//
// Created: MNF 06/13/89 Initial Design and Implementation
// Updated: LGO 08/09/89 Inherit from Generic
// Updated: MBN 09/07/89 Added conditional exception handling
// Updated: MBN 12/15/89 Sprinkled "const" qualifiers all over the place!
// Updated: DLS 03/22/91 New lite version
//
// This is the header file for the regular expression class. An object of
// this class contains a regular expression, in a special "compiled" format.
// This compiled format consists of several slots all kept as the objects
// private data. The cmRegularExpression class provides a convenient way to represent
// regular expressions. It makes it easy to search for the same regular
// expression in many different strings without having to compile a string to
// regular expression format more than necessary.
//
// A regular expression allows a programmer to specify complex patterns that
// can be searched for and matched against the character string of a String
// object. In its simplest case, a regular expression is a sequence of
// characters with which you can search for exact character matches. However,
// many times you may not know the exact sequence you want to find, or you may
// only want to find a match at the beginning or end of a String. The cmRegularExpression
// object allows specification of such patterns by utilizing the following
// regular expression meta-characters (note that more one of these
// meta-characters can be used in a single regular expression in order to
// create complex search patterns):
//
// ^ Match at beginning of line
// $ Match at end of line
// . Match any single character
// [ ] Match any one character inside the brackets
// [^ ] Match any character NOT inside the brackets
// - Match any character in range on either side of dash
// * Match preceding pattern zero or more times
// + Match preceding pattern one or more times
// ? Match preceding pattern zero or once only
// () Save a matched expression and use it in a further match.
//
// There are three constructors for cmRegularExpression. One just creates an empty cmRegularExpression
// object. Another creates a cmRegularExpression object and initializes it with a regular
// expression that is given in the form of a char*. The third takes a
// reference to a cmRegularExpression object as an argument and creates an object
// initialized with the information from the given cmRegularExpression object.
//
// The find member function finds the first occurence of the regualr
// expression of that object in the string given to find as an argument. Find
// returns a boolean, and if true, mutates the private data appropriately.
// Find sets pointers to the beginning and end of the thing last found, they
// are pointers into the actual string that was searched. The start and end
// member functions return indicies into the searched string that correspond
// to the beginning and end pointers respectively. The compile member
// function takes a char* and puts the compiled version of the char* argument
// into the object's private data fields. The == and != operators only check
// the to see if the compiled regular expression is the same, and the
// deep_equal functions also checks to see if the start and end pointers are
// the same. The is_valid function returns false if program is set to NULL,
// (i.e. there is no valid compiled exression). The set_invalid function sets
// the program to NULL (Warning: this deletes the compiled expression). The
// following examples may help clarify regular expression usage:
//
// * The regular expression "^hello" matches a "hello" only at the
// beginning of a line. It would match "hello there" but not "hi,
// hello there".
//
// * The regular expression "long$" matches a "long" only at the end
// of a line. It would match "so long\0", but not "long ago".
//
// * The regular expression "t..t..g" will match anything that has a
// "t" then any two characters, another "t", any two characters and
// then a "g". It will match "testing", or "test again" but would
// not match "toasting"
//
// * The regular expression "[1-9ab]" matches any number one through
// nine, and the characters "a" and "b". It would match "hello 1"
// or "begin", but would not match "no-match".
//
// * The regular expression "[^1-9ab]" matches any character that is
// not a number one through nine, or an "a" or "b". It would NOT
// match "hello 1" or "begin", but would match "no-match".
//
// * The regular expression "br* " matches something that begins with
// a "b", is followed by zero or more "r"s, and ends in a space. It
// would match "brrrrr ", and "b ", but would not match "brrh ".
//
// * The regular expression "br+ " matches something that begins with
// a "b", is followed by one or more "r"s, and ends in a space. It
// would match "brrrrr ", and "br ", but would not match "b " or
// "brrh ".
//
// * The regular expression "br? " matches something that begins with
// a "b", is followed by zero or one "r"s, and ends in a space. It
// would match "br ", and "b ", but would not match "brrrr " or
// "brrh ".
//
// * The regular expression "(..p)b" matches something ending with pb
// and beginning with whatever the two characters before the first p
// encounterd in the line were. It would find "repb" in "rep drepa
// qrepb". The regular expression "(..p)a" would find "repa qrepb"
// in "rep drepa qrepb"
//
// * The regular expression "d(..p)" matches something ending with p,
// beginning with d, and having two characters in between that are
// the same as the two characters before the first p encounterd in
// the line. It would match "drepa qrepb" in "rep drepa qrepb".
//
#include "cmRegularExpression.h" // Include class specification
#include <stdio.h>
#include <string>
// cmRegularExpression -- Copies the given regular expression.
cmRegularExpression::cmRegularExpression (const cmRegularExpression& rxp) {
int ind;
this->progsize = rxp.progsize; // Copy regular expression size
this->program = new char[this->progsize]; // Allocate storage
for(ind=this->progsize; ind-- != 0;) // Copy regular expresion
this->program[ind] = rxp.program[ind];
this->startp[0] = rxp.startp[0]; // Copy pointers into last
this->endp[0] = rxp.endp[0]; // Successful "find" operation
this->regmust = rxp.regmust; // Copy field
if (rxp.regmust != NULL) {
char* dum = rxp.program;
ind = 0;
while (dum != rxp.regmust) {
++dum;
++ind;
}
this->regmust = this->program + ind;
}
this->regstart = rxp.regstart; // Copy starting index
this->reganch = rxp.reganch; // Copy remaining private data
this->regmlen = rxp.regmlen; // Copy remaining private data
}
// operator== -- Returns true if two regular expressions have the same
// compiled program for pattern matching.
bool cmRegularExpression::operator== (const cmRegularExpression& rxp) const {
if (this != &rxp) { // Same address?
int ind = this->progsize; // Get regular expression size
if (ind != rxp.progsize) // If different size regexp
return false; // Return failure
while(ind-- != 0) // Else while still characters
if(this->program[ind] != rxp.program[ind]) // If regexp are different
return false; // Return failure
}
return true; // Else same, return success
}
// deep_equal -- Returns true if have the same compiled regular expressions
// and the same start and end pointers.
bool cmRegularExpression::deep_equal (const cmRegularExpression& rxp) const {
int ind = this->progsize; // Get regular expression size
if (ind != rxp.progsize) // If different size regexp
return false; // Return failure
while(ind-- != 0) // Else while still characters
if(this->program[ind] != rxp.program[ind]) // If regexp are different
return false; // Return failure
return (this->startp[0] == rxp.startp[0] && // Else if same start/end ptrs,
this->endp[0] == rxp.endp[0]); // Return true
}
// The remaining code in this file is derived from the regular expression code
// whose copyright statement appears below. It has been changed to work
// with the class concepts of C++ and COOL.
/*
* compile and find
*
* Copyright (c) 1986 by University of Toronto.
* Written by Henry Spencer. Not derived from licensed software.
*
* Permission is granted to anyone to use this software for any
* purpose on any computer system, and to redistribute it freely,
* subject to the following restrictions:
*
* 1. The author is not responsible for the consequences of use of
* this software, no matter how awful, even if they arise
* from defects in it.
*
* 2. The origin of this software must not be misrepresented, either
* by explicit claim or by omission.
*
* 3. Altered versions must be plainly marked as such, and must not
* be misrepresented as being the original software.
*
* Beware that some of this code is subtly aware of the way operator
* precedence is structured in regular expressions. Serious changes in
* regular-expression syntax might require a total rethink.
*/
/*
* The "internal use only" fields in regexp.h are present to pass info from
* compile to execute that permits the execute phase to run lots faster on
* simple cases. They are:
*
* regstart char that must begin a match; '\0' if none obvious
* reganch is the match anchored (at beginning-of-line only)?
* regmust string (pointer into program) that match must include, or NULL
* regmlen length of regmust string
*
* Regstart and reganch permit very fast decisions on suitable starting points
* for a match, cutting down the work a lot. Regmust permits fast rejection
* of lines that cannot possibly match. The regmust tests are costly enough
* that compile() supplies a regmust only if the r.e. contains something
* potentially expensive (at present, the only such thing detected is * or +
* at the start of the r.e., which can involve a lot of backup). Regmlen is
* supplied because the test in find() needs it and compile() is computing
* it anyway.
*/
/*
* Structure for regexp "program". This is essentially a linear encoding
* of a nondeterministic finite-state machine (aka syntax charts or
* "railroad normal form" in parsing technology). Each node is an opcode
* plus a "next" pointer, possibly plus an operand. "Next" pointers of
* all nodes except BRANCH implement concatenation; a "next" pointer with
* a BRANCH on both ends of it is connecting two alternatives. (Here we
* have one of the subtle syntax dependencies: an individual BRANCH (as
* opposed to a collection of them) is never concatenated with anything
* because of operator precedence.) The operand of some types of node is
* a literal string; for others, it is a node leading into a sub-FSM. In
* particular, the operand of a BRANCH node is the first node of the branch.
* (NB this is *not* a tree structure: the tail of the branch connects
* to the thing following the set of BRANCHes.) The opcodes are:
*/
// definition number opnd? meaning
#define END 0 // no End of program.
#define BOL 1 // no Match "" at beginning of line.
#define EOL 2 // no Match "" at end of line.
#define ANY 3 // no Match any one character.
#define ANYOF 4 // str Match any character in this string.
#define ANYBUT 5 // str Match any character not in this
// string.
#define BRANCH 6 // node Match this alternative, or the
// next...
#define BACK 7 // no Match "", "next" ptr points backward.
#define EXACTLY 8 // str Match this string.
#define NOTHING 9 // no Match empty string.
#define STAR 10 // node Match this (simple) thing 0 or more
// times.
#define PLUS 11 // node Match this (simple) thing 1 or more
// times.
#define OPEN 20 // no Mark this point in input as start of
// #n.
// OPEN+1 is number 1, etc.
#define CLOSE 30 // no Analogous to OPEN.
/*
* Opcode notes:
*
* BRANCH The set of branches constituting a single choice are hooked
* together with their "next" pointers, since precedence prevents
* anything being concatenated to any individual branch. The
* "next" pointer of the last BRANCH in a choice points to the
* thing following the whole choice. This is also where the
* final "next" pointer of each individual branch points; each
* branch starts with the operand node of a BRANCH node.
*
* BACK Normal "next" pointers all implicitly point forward; BACK
* exists to make loop structures possible.
*
* STAR,PLUS '?', and complex '*' and '+', are implemented as circular
* BRANCH structures using BACK. Simple cases (one character
* per match) are implemented with STAR and PLUS for speed
* and to minimize recursive plunges.
*
* OPEN,CLOSE ...are numbered at compile time.
*/
/*
* A node is one char of opcode followed by two chars of "next" pointer.
* "Next" pointers are stored as two 8-bit pieces, high order first. The
* value is a positive offset from the opcode of the node containing it.
* An operand, if any, simply follows the node. (Note that much of the
* code generation knows about this implicit relationship.)
*
* Using two bytes for the "next" pointer is vast overkill for most things,
* but allows patterns to get big without disasters.
*/
#define OP(p) (*(p))
#define NEXT(p) (((*((p)+1)&0377)<<8) + (*((p)+2)&0377))
#define OPERAND(p) ((p) + 3)
const unsigned char MAGIC = 0234;
/*
* Utility definitions.
*/
#define UCHARAT(p) ((const unsigned char*)(p))[0]
#define FAIL(m) { regerror(m); return(NULL); }
#define ISMULT(c) ((c) == '*' || (c) == '+' || (c) == '?')
#define META "^$.[()|?+*\\"
/*
* Flags to be passed up and down.
*/
#define HASWIDTH 01 // Known never to match null string.
#define SIMPLE 02 // Simple enough to be STAR/PLUS operand.
#define SPSTART 04 // Starts with * or +.
#define WORST 0 // Worst case.
/////////////////////////////////////////////////////////////////////////
//
// COMPILE AND ASSOCIATED FUNCTIONS
//
/////////////////////////////////////////////////////////////////////////
/*
* Global work variables for compile().
*/
static const char* regparse; // Input-scan pointer.
static int regnpar; // () count.
static char regdummy;
static char* regcode; // Code-emit pointer; &regdummy = don't.
static long regsize; // Code size.
/*
* Forward declarations for compile()'s friends.
*/
// #ifndef static
// #define static static
// #endif
static char* reg (int, int*);
static char* regbranch (int*);
static char* regpiece (int*);
static char* regatom (int*);
static char* regnode (char);
static const char* regnext (register const char*);
static char* regnext (register char*);
static void regc (unsigned char);
static void reginsert (char, char*);
static void regtail (char*, const char*);
static void regoptail (char*, const char*);
#ifdef STRCSPN
static int strcspn ();
#endif
/*
* We can't allocate space until we know how big the compiled form will be,
* but we can't compile it (and thus know how big it is) until we've got a
* place to put the code. So we cheat: we compile it twice, once with code
* generation turned off and size counting turned on, and once "for real".
* This also means that we don't allocate space until we are sure that the
* thing really will compile successfully, and we never have to move the
* code and thus invalidate pointers into it. (Note that it has to be in
* one piece because free() must be able to free it all.)
*
* Beware that the optimization-preparation code in here knows about some
* of the structure of the compiled regexp.
*/
// compile -- compile a regular expression into internal code
// for later pattern matching.
void cmRegularExpression::compile (const char* exp) {
register const char* scan;
register const char* longest;
register unsigned long len;
int flags;
if (exp == NULL) {
//RAISE Error, SYM(cmRegularExpression), SYM(No_Expr),
printf ("cmRegularExpression::compile(): No expression supplied.\n");
return;
}
// First pass: determine size, legality.
regparse = exp;
regnpar = 1;
regsize = 0L;
regcode = &regdummy;
regc(MAGIC);
if(!reg(0, &flags))
{
printf ("cmRegularExpression::compile(): Error in compile.\n");
return;
}
this->startp[0] = this->endp[0] = this->searchstring = NULL;
// Small enough for pointer-storage convention?
if (regsize >= 32767L) { // Probably could be 65535L.
//RAISE Error, SYM(cmRegularExpression), SYM(Expr_Too_Big),
printf ("cmRegularExpression::compile(): Expression too big.\n");
return;
}
// Allocate space.
//#ifndef WIN32
if (this->program != NULL) delete [] this->program;
//#endif
this->program = new char[regsize];
this->progsize = (int) regsize;
if (this->program == NULL) {
//RAISE Error, SYM(cmRegularExpression), SYM(Out_Of_Memory),
printf ("cmRegularExpression::compile(): Out of memory.\n");
return;
}
// Second pass: emit code.
regparse = exp;
regnpar = 1;
regcode = this->program;
regc(MAGIC);
reg(0, &flags);
// Dig out information for optimizations.
this->regstart = '\0'; // Worst-case defaults.
this->reganch = 0;
this->regmust = NULL;
this->regmlen = 0;
scan = this->program + 1; // First BRANCH.
if (OP(regnext(scan)) == END) { // Only one top-level choice.
scan = OPERAND(scan);
// Starting-point info.
if (OP(scan) == EXACTLY)
this->regstart = *OPERAND(scan);
else if (OP(scan) == BOL)
this->reganch++;
//
// If there's something expensive in the r.e., find the longest
// literal string that must appear and make it the regmust. Resolve
// ties in favor of later strings, since the regstart check works
// with the beginning of the r.e. and avoiding duplication
// strengthens checking. Not a strong reason, but sufficient in the
// absence of others.
//
if (flags & SPSTART) {
longest = NULL;
len = 0;
for (; scan != NULL; scan = regnext(scan))
if (OP(scan) == EXACTLY && strlen(OPERAND(scan)) >= len) {
longest = OPERAND(scan);
len = strlen(OPERAND(scan));
}
this->regmust = longest;
this->regmlen = len;
}
}
}
/*
- reg - regular expression, i.e. main body or parenthesized thing
*
* Caller must absorb opening parenthesis.
*
* Combining parenthesis handling with the base level of regular expression
* is a trifle forced, but the need to tie the tails of the branches to what
* follows makes it hard to avoid.
*/
static char* reg (int paren, int *flagp) {
register char* ret;
register char* br;
register char* ender;
register int parno =0;
int flags;
*flagp = HASWIDTH; // Tentatively.
// Make an OPEN node, if parenthesized.
if (paren) {
if (regnpar >= NSUBEXP) {
//RAISE Error, SYM(cmRegularExpression), SYM(Too_Many_Parens),
printf ("cmRegularExpression::compile(): Too many parentheses.\n");
return 0;
}
parno = regnpar;
regnpar++;
ret = regnode(OPEN + parno);
}
else
ret = NULL;
// Pick up the branches, linking them together.
br = regbranch(&flags);
if (br == NULL)
return (NULL);
if (ret != NULL)
regtail(ret, br); // OPEN -> first.
else
ret = br;
if (!(flags & HASWIDTH))
*flagp &= ~HASWIDTH;
*flagp |= flags & SPSTART;
while (*regparse == '|') {
regparse++;
br = regbranch(&flags);
if (br == NULL)
return (NULL);
regtail(ret, br); // BRANCH -> BRANCH.
if (!(flags & HASWIDTH))
*flagp &= ~HASWIDTH;
*flagp |= flags & SPSTART;
}
// Make a closing node, and hook it on the end.
ender = regnode((paren) ? CLOSE + parno : END);
regtail(ret, ender);
// Hook the tails of the branches to the closing node.
for (br = ret; br != NULL; br = regnext(br))
regoptail(br, ender);
// Check for proper termination.
if (paren && *regparse++ != ')') {
//RAISE Error, SYM(cmRegularExpression), SYM(Unmatched_Parens),
printf ("cmRegularExpression::compile(): Unmatched parentheses.\n");
return 0;
}
else if (!paren && *regparse != '\0') {
if (*regparse == ')') {
//RAISE Error, SYM(cmRegularExpression), SYM(Unmatched_Parens),
printf ("cmRegularExpression::compile(): Unmatched parentheses.\n");
return 0;
}
else {
//RAISE Error, SYM(cmRegularExpression), SYM(Internal_Error),
printf ("cmRegularExpression::compile(): Internal error.\n");
return 0;
}
// NOTREACHED
}
return (ret);
}
/*
- regbranch - one alternative of an | operator
*
* Implements the concatenation operator.
*/
static char* regbranch (int *flagp) {
register char* ret;
register char* chain;
register char* latest;
int flags;
*flagp = WORST; // Tentatively.
ret = regnode(BRANCH);
chain = NULL;
while (*regparse != '\0' && *regparse != '|' && *regparse != ')') {
latest = regpiece(&flags);
if (latest == NULL)
return (NULL);
*flagp |= flags & HASWIDTH;
if (chain == NULL) // First piece.
*flagp |= flags & SPSTART;
else
regtail(chain, latest);
chain = latest;
}
if (chain == NULL) // Loop ran zero times.
regnode(NOTHING);
return (ret);
}
/*
- regpiece - something followed by possible [*+?]
*
* Note that the branching code sequences used for ? and the general cases
* of * and + are somewhat optimized: they use the same NOTHING node as
* both the endmarker for their branch list and the body of the last branch.
* It might seem that this node could be dispensed with entirely, but the
* endmarker role is not redundant.
*/
static char* regpiece (int *flagp) {
register char* ret;
register char op;
register char* next;
int flags;
ret = regatom(&flags);
if (ret == NULL)
return (NULL);
op = *regparse;
if (!ISMULT(op)) {
*flagp = flags;
return (ret);
}
if (!(flags & HASWIDTH) && op != '?') {
//RAISE Error, SYM(cmRegularExpression), SYM(Empty_Operand),
printf ("cmRegularExpression::compile() : *+ operand could be empty.\n");
return 0;
}
*flagp = (op != '+') ? (WORST | SPSTART) : (WORST | HASWIDTH);
if (op == '*' && (flags & SIMPLE))
reginsert(STAR, ret);
else if (op == '*') {
// Emit x* as (x&|), where & means "self".
reginsert(BRANCH, ret); // Either x
regoptail(ret, regnode(BACK)); // and loop
regoptail(ret, ret); // back
regtail(ret, regnode(BRANCH)); // or
regtail(ret, regnode(NOTHING)); // null.
}
else if (op == '+' && (flags & SIMPLE))
reginsert(PLUS, ret);
else if (op == '+') {
// Emit x+ as x(&|), where & means "self".
next = regnode(BRANCH); // Either
regtail(ret, next);
regtail(regnode(BACK), ret); // loop back
regtail(next, regnode(BRANCH)); // or
regtail(ret, regnode(NOTHING)); // null.
}
else if (op == '?') {
// Emit x? as (x|)
reginsert(BRANCH, ret); // Either x
regtail(ret, regnode(BRANCH)); // or
next = regnode(NOTHING);// null.
regtail(ret, next);
regoptail(ret, next);
}
regparse++;
if (ISMULT(*regparse)) {
//RAISE Error, SYM(cmRegularExpression), SYM(Nested_Operand),
printf ("cmRegularExpression::compile(): Nested *?+.\n");
return 0;
}
return (ret);
}
/*
- regatom - the lowest level
*
* Optimization: gobbles an entire sequence of ordinary characters so that
* it can turn them into a single node, which is smaller to store and
* faster to run. Backslashed characters are exceptions, each becoming a
* separate node; the code is simpler that way and it's not worth fixing.
*/
static char* regatom (int *flagp) {
register char* ret;
int flags;
*flagp = WORST; // Tentatively.
switch (*regparse++) {
case '^':
ret = regnode(BOL);
break;
case '$':
ret = regnode(EOL);
break;
case '.':
ret = regnode(ANY);
*flagp |= HASWIDTH | SIMPLE;
break;
case '[':{
register int rxpclass;
register int rxpclassend;
if (*regparse == '^') { // Complement of range.
ret = regnode(ANYBUT);
regparse++;
}
else
ret = regnode(ANYOF);
if (*regparse == ']' || *regparse == '-')
regc(*regparse++);
while (*regparse != '\0' && *regparse != ']') {
if (*regparse == '-') {
regparse++;
if (*regparse == ']' || *regparse == '\0')
regc('-');
else {
rxpclass = UCHARAT(regparse - 2) + 1;
rxpclassend = UCHARAT(regparse);
if (rxpclass > rxpclassend + 1) {
//RAISE Error, SYM(cmRegularExpression), SYM(Invalid_Range),
printf ("cmRegularExpression::compile(): Invalid range in [].\n");
return 0;
}
for (; rxpclass <= rxpclassend; rxpclass++)
regc(rxpclass);
regparse++;
}
}
else
regc(*regparse++);
}
regc('\0');
if (*regparse != ']') {
//RAISE Error, SYM(cmRegularExpression), SYM(Unmatched_Bracket),
printf ("cmRegularExpression::compile(): Unmatched [].\n");
return 0;
}
regparse++;
*flagp |= HASWIDTH | SIMPLE;
}
break;
case '(':
ret = reg(1, &flags);
if (ret == NULL)
return (NULL);
*flagp |= flags & (HASWIDTH | SPSTART);
break;
case '\0':
case '|':
case ')':
//RAISE Error, SYM(cmRegularExpression), SYM(Internal_Error),
printf ("cmRegularExpression::compile(): Internal error.\n"); // Never here
return 0;
case '?':
case '+':
case '*':
//RAISE Error, SYM(cmRegularExpression), SYM(No_Operand),
printf ("cmRegularExpression::compile(): ?+* follows nothing.\n");
return 0;
case '\\':
if (*regparse == '\0') {
//RAISE Error, SYM(cmRegularExpression), SYM(Trailing_Backslash),
printf ("cmRegularExpression::compile(): Trailing backslash.\n");
return 0;
}
ret = regnode(EXACTLY);
regc(*regparse++);
regc('\0');
*flagp |= HASWIDTH | SIMPLE;
break;
default:{
register int len;
register char ender;
regparse--;
len = strcspn(regparse, META);
if (len <= 0) {
//RAISE Error, SYM(cmRegularExpression), SYM(Internal_Error),
printf ("cmRegularExpression::compile(): Internal error.\n");
return 0;
}
ender = *(regparse + len);
if (len > 1 && ISMULT(ender))
len--; // Back off clear of ?+* operand.
*flagp |= HASWIDTH;
if (len == 1)
*flagp |= SIMPLE;
ret = regnode(EXACTLY);
while (len > 0) {
regc(*regparse++);
len--;
}
regc('\0');
}
break;
}
return (ret);
}
/*
- regnode - emit a node
Location.
*/
static char* regnode (char op) {
register char* ret;
register char* ptr;
ret = regcode;
if (ret == &regdummy) {
regsize += 3;
return (ret);
}
ptr = ret;
*ptr++ = op;
*ptr++ = '\0'; // Null "next" pointer.
*ptr++ = '\0';
regcode = ptr;
return (ret);
}
/*
- regc - emit (if appropriate) a byte of code
*/
static void regc (unsigned char b) {
if (regcode != &regdummy)
*regcode++ = b;
else
regsize++;
}
/*
- reginsert - insert an operator in front of already-emitted operand
*
* Means relocating the operand.
*/
static void reginsert (char op, char* opnd) {
register char* src;
register char* dst;
register char* place;
if (regcode == &regdummy) {
regsize += 3;
return;
}
src = regcode;
regcode += 3;
dst = regcode;
while (src > opnd)
*--dst = *--src;
place = opnd; // Op node, where operand used to be.
*place++ = op;
*place++ = '\0';
*place++ = '\0';
}
/*
- regtail - set the next-pointer at the end of a node chain
*/
static void regtail (char* p, const char* val) {
register char* scan;
register char* temp;
register int offset;
if (p == &regdummy)
return;
// Find last node.
scan = p;
for (;;) {
temp = regnext(scan);
if (temp == NULL)
break;
scan = temp;
}
if (OP(scan) == BACK)
offset = (const char*)scan - val;
else
offset = val - scan;
*(scan + 1) = (offset >> 8) & 0377;
*(scan + 2) = offset & 0377;
}
/*
- regoptail - regtail on operand of first argument; nop if operandless
*/
static void regoptail (char* p, const char* val) {
// "Operandless" and "op != BRANCH" are synonymous in practice.
if (p == NULL || p == &regdummy || OP(p) != BRANCH)
return;
regtail(OPERAND(p), val);
}
////////////////////////////////////////////////////////////////////////
//
// find and friends
//
////////////////////////////////////////////////////////////////////////
/*
* Global work variables for find().
*/
static const char* reginput; // String-input pointer.
static const char* regbol; // Beginning of input, for ^ check.
static const char* *regstartp; // Pointer to startp array.
static const char* *regendp; // Ditto for endp.
/*
* Forwards.
*/
static int regtry (const char*, const char* *,
const char* *, const char*);
static int regmatch (const char*);
static int regrepeat (const char*);
#ifdef DEBUG
int regnarrate = 0;
void regdump ();
static char* regprop ();
#endif
bool cmRegularExpression::find (std::string const& s) {
return find(s.c_str());
}
// find -- Matches the regular expression to the given string.
// Returns true if found, and sets start and end indexes accordingly.
bool cmRegularExpression::find (const char* string) {
register const char* s;
this->searchstring = string;
// Check validity of program.
if (!this->program || UCHARAT(this->program) != MAGIC) {
//RAISE Error, SYM(cmRegularExpression), SYM(Internal_Error),
printf ("cmRegularExpression::find(): Compiled regular expression corrupted.\n");
return 0;
}
// If there is a "must appear" string, look for it.
if (this->regmust != NULL) {
s = string;
while ((s = strchr(s, this->regmust[0])) != NULL) {
if (strncmp(s, this->regmust, this->regmlen) == 0)
break; // Found it.
s++;
}
if (s == NULL) // Not present.
return (0);
}
// Mark beginning of line for ^ .
regbol = string;
// Simplest case: anchored match need be tried only once.
if (this->reganch)
return (regtry(string, this->startp, this->endp, this->program) != 0);
// Messy cases: unanchored match.
s = string;
if (this->regstart != '\0')
// We know what char it must start with.
while ((s = strchr(s, this->regstart)) != NULL) {
if (regtry(s, this->startp, this->endp, this->program))
return (1);
s++;
}
else
// We don't -- general case.
do {
if (regtry(s, this->startp, this->endp, this->program))
return (1);
} while (*s++ != '\0');
// Failure.
return (0);
}
/*
- regtry - try match at specific point
0 failure, 1 success
*/
static int regtry (const char* string, const char* *start,
const char* *end, const char* prog) {
register int i;
register const char* *sp1;
register const char* *ep;
reginput = string;
regstartp = start;
regendp = end;
sp1 = start;
ep = end;
for (i = NSUBEXP; i > 0; i--) {
*sp1++ = NULL;
*ep++ = NULL;
}
if (regmatch(prog + 1)) {
start[0] = string;
end[0] = reginput;
return (1);
}
else
return (0);
}
/*
- regmatch - main matching routine
*
* Conceptually the strategy is simple: check to see whether the current
* node matches, call self recursively to see whether the rest matches,
* and then act accordingly. In practice we make some effort to avoid
* recursion, in particular by going through "ordinary" nodes (that don't
* need to know whether the rest of the match failed) by a loop instead of
* by recursion.
* 0 failure, 1 success
*/
static int regmatch (const char* prog) {
register const char* scan; // Current node.
const char* next; // Next node.
scan = prog;
while (scan != NULL) {
next = regnext(scan);
switch (OP(scan)) {
case BOL:
if (reginput != regbol)
return (0);
break;
case EOL:
if (*reginput != '\0')
return (0);
break;
case ANY:
if (*reginput == '\0')
return (0);
reginput++;
break;
case EXACTLY:{
register int len;
register const char* opnd;
opnd = OPERAND(scan);
// Inline the first character, for speed.
if (*opnd != *reginput)
return (0);
len = strlen(opnd);
if (len > 1 && strncmp(opnd, reginput, len) != 0)
return (0);
reginput += len;
}
break;
case ANYOF:
if (*reginput == '\0' || strchr(OPERAND(scan), *reginput) == NULL)
return (0);
reginput++;
break;
case ANYBUT:
if (*reginput == '\0' || strchr(OPERAND(scan), *reginput) != NULL)
return (0);
reginput++;
break;
case NOTHING:
break;
case BACK:
break;
case OPEN + 1:
case OPEN + 2:
case OPEN + 3:
case OPEN + 4:
case OPEN + 5:
case OPEN + 6:
case OPEN + 7:
case OPEN + 8:
case OPEN + 9:{
register int no;
register const char* save;
no = OP(scan) - OPEN;
save = reginput;
if (regmatch(next)) {
//
// Don't set startp if some later invocation of the
// same parentheses already has.
//
if (regstartp[no] == NULL)
regstartp[no] = save;
return (1);
}
else
return (0);
}
// break;
case CLOSE + 1:
case CLOSE + 2:
case CLOSE + 3:
case CLOSE + 4:
case CLOSE + 5:
case CLOSE + 6:
case CLOSE + 7:
case CLOSE + 8:
case CLOSE + 9:{
register int no;
register const char* save;
no = OP(scan) - CLOSE;
save = reginput;
if (regmatch(next)) {
//
// Don't set endp if some later invocation of the
// same parentheses already has.
//
if (regendp[no] == NULL)
regendp[no] = save;
return (1);
}
else
return (0);
}
// break;
case BRANCH:{
register const char* save;
if (OP(next) != BRANCH) // No choice.
next = OPERAND(scan); // Avoid recursion.
else {
do {
save = reginput;
if (regmatch(OPERAND(scan)))
return (1);
reginput = save;
scan = regnext(scan);
} while (scan != NULL && OP(scan) == BRANCH);
return (0);
// NOTREACHED
}
}
break;
case STAR:
case PLUS:{
register char nextch;
register int no;
register const char* save;
register int min_no;
//
// Lookahead to avoid useless match attempts when we know
// what character comes next.
//
nextch = '\0';
if (OP(next) == EXACTLY)
nextch = *OPERAND(next);
min_no = (OP(scan) == STAR) ? 0 : 1;
save = reginput;
no = regrepeat(OPERAND(scan));
while (no >= min_no) {
// If it could work, try it.
if (nextch == '\0' || *reginput == nextch)
if (regmatch(next))
return (1);
// Couldn't or didn't -- back up.
no--;
reginput = save + no;
}
return (0);
}
// break;
case END:
return (1); // Success!
default:
//RAISE Error, SYM(cmRegularExpression), SYM(Internal_Error),
printf ("cmRegularExpression::find(): Internal error -- memory corrupted.\n");
return 0;
}
scan = next;
}
//
// We get here only if there's trouble -- normally "case END" is the
// terminating point.
//
//RAISE Error, SYM(cmRegularExpression), SYM(Internal_Error),
printf ("cmRegularExpression::find(): Internal error -- corrupted pointers.\n");
return (0);
}
/*
- regrepeat - repeatedly match something simple, report how many
*/
static int regrepeat (const char* p) {
register int count = 0;
register const char* scan;
register const char* opnd;
scan = reginput;
opnd = OPERAND(p);
switch (OP(p)) {
case ANY:
count = strlen(scan);
scan += count;
break;
case EXACTLY:
while (*opnd == *scan) {
count++;
scan++;
}
break;
case ANYOF:
while (*scan != '\0' && strchr(opnd, *scan) != NULL) {
count++;
scan++;
}
break;
case ANYBUT:
while (*scan != '\0' && strchr(opnd, *scan) == NULL) {
count++;
scan++;
}
break;
default: // Oh dear. Called inappropriately.
//RAISE Error, SYM(cmRegularExpression), SYM(Internal_Error),
printf ("cm RegularExpression::find(): Internal error.\n");
return 0;
}
reginput = scan;
return (count);
}
/*
- regnext - dig the "next" pointer out of a node
*/
static const char* regnext (register const char* p) {
register int offset;
if (p == &regdummy)
return (NULL);
offset = NEXT(p);
if (offset == 0)
return (NULL);
if (OP(p) == BACK)
return (p - offset);
else
return (p + offset);
}
static char* regnext (register char* p) {
register int offset;
if (p == &regdummy)
return (NULL);
offset = NEXT(p);
if (offset == 0)
return (NULL);
if (OP(p) == BACK)
return (p - offset);
else
return (p + offset);
}