Objects/tupleobject.c


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/* Tuple object implementation */

#include "Python.h"

/* Speed optimization to avoid frequent malloc/free of small tuples */
#ifndef MAXSAVESIZE
#define MAXSAVESIZE	20  /* Largest tuple to save on free list */
#endif
#ifndef MAXSAVEDTUPLES 
#define MAXSAVEDTUPLES  2000  /* Maximum number of tuples of each size to save */
#endif

#if MAXSAVESIZE > 0
/* Entries 1 up to MAXSAVESIZE are free lists, entry 0 is the empty
   tuple () of which at most one instance will be allocated.
*/
static PyTupleObject *free_tuples[MAXSAVESIZE];
static int num_free_tuples[MAXSAVESIZE];
#endif
#ifdef COUNT_ALLOCS
int fast_tuple_allocs;
int tuple_zero_allocs;
#endif

PyObject *
PyTuple_New(register int size)
{
	register int i;
	register PyTupleObject *op;
	if (size < 0) {
		PyErr_BadInternalCall();
		return NULL;
	}
#if MAXSAVESIZE > 0
	if (size == 0 && free_tuples[0]) {
		op = free_tuples[0];
		Py_INCREF(op);
#ifdef COUNT_ALLOCS
		tuple_zero_allocs++;
#endif
		return (PyObject *) op;
	}
	if (0 < size && size < MAXSAVESIZE &&
	    (op = free_tuples[size]) != NULL)
	{
		free_tuples[size] = (PyTupleObject *) op->ob_item[0];
		num_free_tuples[size]--;
#ifdef COUNT_ALLOCS
		fast_tuple_allocs++;
#endif
		/* PyObject_InitVar is inlined */
#ifdef Py_TRACE_REFS
		op->ob_size = size;
		op->ob_type = &PyTuple_Type;
#endif
		_Py_NewReference((PyObject *)op);
	}
	else
#endif
	{
		int nbytes = size * sizeof(PyObject *);
		/* Check for overflow */
		if (nbytes / sizeof(PyObject *) != (size_t)size ||
		    (nbytes += sizeof(PyTupleObject) - sizeof(PyObject *))
		    <= 0)
		{
			return PyErr_NoMemory();
		}
		op = PyObject_GC_NewVar(PyTupleObject, &PyTuple_Type, size);
		if (op == NULL)
			return NULL;
	}
	for (i = 0; i < size; i++)
		op->ob_item[i] = NULL;
#if MAXSAVESIZE > 0
	if (size == 0) {
		free_tuples[0] = op;
		++num_free_tuples[0];
		Py_INCREF(op);	/* extra INCREF so that this is never freed */
	}
#endif
	_PyObject_GC_TRACK(op);
	return (PyObject *) op;
}

int
PyTuple_Size(register PyObject *op)
{
	if (!PyTuple_Check(op)) {
		PyErr_BadInternalCall();
		return -1;
	}
	else
		return ((PyTupleObject *)op)->ob_size;
}

PyObject *
PyTuple_GetItem(register PyObject *op, register int i)
{
	if (!PyTuple_Check(op)) {
		PyErr_BadInternalCall();
		return NULL;
	}
	if (i < 0 || i >= ((PyTupleObject *)op) -> ob_size) {
		PyErr_SetString(PyExc_IndexError, "tuple index out of range");
		return NULL;
	}
	return ((PyTupleObject *)op) -> ob_item[i];
}

int
PyTuple_SetItem(register PyObject *op, register int i, PyObject *newitem)
{
	register PyObject *olditem;
	register PyObject **p;
	if (!PyTuple_Check(op) || op->ob_refcnt != 1) {
		Py_XDECREF(newitem);
		PyErr_BadInternalCall();
		return -1;
	}
	if (i < 0 || i >= ((PyTupleObject *)op) -> ob_size) {
		Py_XDECREF(newitem);
		PyErr_SetString(PyExc_IndexError,
				"tuple assignment index out of range");
		return -1;
	}
	p = ((PyTupleObject *)op) -> ob_item + i;
	olditem = *p;
	*p = newitem;
	Py_XDECREF(olditem);
	return 0;
}

/* Methods */

static void
tupledealloc(register PyTupleObject *op)
{
	register int i;
	register int len =  op->ob_size;
	Py_TRASHCAN_SAFE_BEGIN(op)
	_PyObject_GC_UNTRACK(op);
	if (len > 0) {
		i = len;
		while (--i >= 0)
			Py_XDECREF(op->ob_item[i]);
#if MAXSAVESIZE > 0
		if (len < MAXSAVESIZE &&
		    num_free_tuples[len] < MAXSAVEDTUPLES &&
		    op->ob_type == &PyTuple_Type)
		{
			op->ob_item[0] = (PyObject *) free_tuples[len];
			num_free_tuples[len]++;
			free_tuples[len] = op;
			goto done; /* return */
		}
#endif
	}
	PyObject_GC_Del(op);
done:
	Py_TRASHCAN_SAFE_END(op)
}

static int
tupleprint(PyTupleObject *op, FILE *fp, int flags)
{
	int i;
	fprintf(fp, "(");
	for (i = 0; i < op->ob_size; i++) {
		if (i > 0)
			fprintf(fp, ", ");
		if (PyObject_Print(op->ob_item[i], fp, 0) != 0)
			return -1;
	}
	if (op->ob_size == 1)
		fprintf(fp, ",");
	fprintf(fp, ")");
	return 0;
}

static PyObject *
tuplerepr(PyTupleObject *v)
{
	int i, n;
	PyObject *s, *temp;
	PyObject *pieces, *result = NULL;

	n = v->ob_size;
	if (n == 0)
		return PyString_FromString("()");

	pieces = PyTuple_New(n);
	if (pieces == NULL)
		return NULL;

	/* Do repr() on each element. */
	for (i = 0; i < n; ++i) {
		s = PyObject_Repr(v->ob_item[i]);
		if (s == NULL)
			goto Done;
		PyTuple_SET_ITEM(pieces, i, s);
	}

	/* Add "()" decorations to the first and last items. */
	assert(n > 0);
	s = PyString_FromString("(");
	if (s == NULL)
		goto Done;
	temp = PyTuple_GET_ITEM(pieces, 0);
	PyString_ConcatAndDel(&s, temp);
	PyTuple_SET_ITEM(pieces, 0, s);
	if (s == NULL)
		goto Done;

	s = PyString_FromString(n == 1 ? ",)" : ")");
	if (s == NULL)
		goto Done;
	temp = PyTuple_GET_ITEM(pieces, n-1);
	PyString_ConcatAndDel(&temp, s);
	PyTuple_SET_ITEM(pieces, n-1, temp);
	if (temp == NULL)
		goto Done;

	/* Paste them all together with ", " between. */
	s = PyString_FromString(", ");
	if (s == NULL)
		goto Done;
	result = _PyString_Join(s, pieces);
	Py_DECREF(s);	

Done:
	Py_DECREF(pieces);
	return result;
}

static long
tuplehash(PyTupleObject *v)
{
	register long x, y;
	register int len = v->ob_size;
	register PyObject **p;
	x = 0x345678L;
	p = v->ob_item;
	while (--len >= 0) {
		y = PyObject_Hash(*p++);
		if (y == -1)
			return -1;
		x = (1000003*x) ^ y;
	}
	x ^= v->ob_size;
	if (x == -1)
		x = -2;
	return x;
}

static int
tuplelength(PyTupleObject *a)
{
	return a->ob_size;
}

static int
tuplecontains(PyTupleObject *a, PyObject *el)
{
	int i, cmp;

	for (i = 0; i < a->ob_size; ++i) {
		cmp = PyObject_RichCompareBool(el, PyTuple_GET_ITEM(a, i),
					       Py_EQ);
		if (cmp > 0)
			return 1;
		else if (cmp < 0)
			return -1;
	}
	return 0;
}

static PyObject *
tupleitem(register PyTupleObject *a, register int i)
{
	if (i < 0 || i >= a->ob_size) {
		PyErr_SetString(PyExc_IndexError, "tuple index out of range");
		return NULL;
	}
	Py_INCREF(a->ob_item[i]);
	return a->ob_item[i];
}

static PyObject *
tupleslice(register PyTupleObject *a, register int ilow, register int ihigh)
{
	register PyTupleObject *np;
	register int i;
	if (ilow < 0)
		ilow = 0;
	if (ihigh > a->ob_size)
		ihigh = a->ob_size;
	if (ihigh < ilow)
		ihigh = ilow;
	if (ilow == 0 && ihigh == a->ob_size) {
		/* XXX can only do this if tuples are immutable! */
		Py_INCREF(a);
		return (PyObject *)a;
	}
	np = (PyTupleObject *)PyTuple_New(ihigh - ilow);
	if (np == NULL)
		return NULL;
	for (i = ilow; i < ihigh; i++) {
		PyObject *v = a->ob_item[i];
		Py_INCREF(v);
		np->ob_item[i - ilow] = v;
	}
	return (PyObject *)np;
}

PyObject *
PyTuple_GetSlice(PyObject *op, int i, int j)
{
	if (op == NULL || !PyTuple_Check(op)) {
		PyErr_BadInternalCall();
		return NULL;
	}
	return tupleslice((PyTupleObject *)op, i, j);
}

static PyObject *
tupleconcat(register PyTupleObject *a, register PyObject *bb)
{
	register int size;
	register int i;
	PyTupleObject *np;
	if (!PyTuple_Check(bb)) {
		PyErr_Format(PyExc_TypeError,
       		     "can only concatenate tuple (not \"%.200s\") to tuple",
			     bb->ob_type->tp_name);
		return NULL;
	}
#define b ((PyTupleObject *)bb)
	size = a->ob_size + b->ob_size;
	np = (PyTupleObject *) PyTuple_New(size);
	if (np == NULL) {
		return NULL;
	}
	for (i = 0; i < a->ob_size; i++) {
		PyObject *v = a->ob_item[i];
		Py_INCREF(v);
		np->ob_item[i] = v;
	}
	for (i = 0; i < b->ob_size; i++) {
		PyObject *v = b->ob_item[i];
		Py_INCREF(v);
		np->ob_item[i + a->ob_size] = v;
	}
	return (PyObject *)np;
#undef b
}

static PyObject *
tuplerepeat(PyTupleObject *a, int n)
{
	int i, j;
	int size;
	PyTupleObject *np;
	PyObject **p;
	if (n < 0)
		n = 0;
	if (a->ob_size == 0 || n == 1) {
		/* Since tuples are immutable, we can return a shared
		   copy in this case */
		Py_INCREF(a);
		return (PyObject *)a;
	}
	size = a->ob_size * n;
	if (size/a->ob_size != n)
		return PyErr_NoMemory();
	np = (PyTupleObject *) PyTuple_New(size);
	if (np == NULL)
		return NULL;
	p = np->ob_item;
	for (i = 0; i < n; i++) {
		for (j = 0; j < a->ob_size; j++) {
			*p = a->ob_item[j];
			Py_INCREF(*p);
			p++;
		}
	}
	return (PyObject *) np;
}

static int
tupletraverse(PyTupleObject *o, visitproc visit, void *arg)
{
	int i, err;
	PyObject *x;

	for (i = o->ob_size; --i >= 0; ) {
		x = o->ob_item[i];
		if (x != NULL) {
			err = visit(x, arg);
			if (err)
				return err;
		}
	}
	return 0;
}

static PyObject *
tuplerichcompare(PyObject *v, PyObject *w, int op)
{
	PyTupleObject *vt, *wt;
	int i;
	int vlen, wlen;

	if (!PyTuple_Check(v) || !PyTuple_Check(w)) {
		Py_INCREF(Py_NotImplemented);
		return Py_NotImplemented;
	}

	vt = (PyTupleObject *)v;
	wt = (PyTupleObject *)w;

	vlen = vt->ob_size;
	wlen = wt->ob_size;

	/* Note:  the corresponding code for lists has an "early out" test
	 * here when op is EQ or NE and the lengths differ.  That pays there,
	 * but Tim was unable to find any real code where EQ/NE tuple
	 * compares don't have the same length, so testing for it here would
	 * have cost without benefit.
	 */

	/* Search for the first index where items are different.
	 * Note that because tuples are immutable, it's safe to reuse
	 * vlen and wlen across the comparison calls.
	 */
	for (i = 0; i < vlen && i < wlen; i++) {
		int k = PyObject_RichCompareBool(vt->ob_item[i],
						 wt->ob_item[i], Py_EQ);
		if (k < 0)
			return NULL;
		if (!k)
			break;
	}

	if (i >= vlen || i >= wlen) {
		/* No more items to compare -- compare sizes */
		int cmp;
		PyObject *res;
		switch (op) {
		case Py_LT: cmp = vlen <  wlen; break;
		case Py_LE: cmp = vlen <= wlen; break;
		case Py_EQ: cmp = vlen == wlen; break;
		case Py_NE: cmp = vlen != wlen; break;
		case Py_GT: cmp = vlen >  wlen; break;
		case Py_GE: cmp = vlen >= wlen; break;
		default: return NULL; /* cannot happen */
		}
		if (cmp)
			res = Py_True;
		else
			res = Py_False;
		Py_INCREF(res);
		return res;
	}

	/* We have an item that differs -- shortcuts for EQ/NE */
	if (op == Py_EQ) {
		Py_INCREF(Py_False);
		return Py_False;
	}
	if (op == Py_NE) {
		Py_INCREF(Py_True);
		return Py_True;
	}

	/* Compare the final item again using the proper operator */
	return PyObject_RichCompare(vt->ob_item[i], wt->ob_item[i], op);
}

staticforward PyObject *
tuple_subtype_new(PyTypeObject *type, PyObject *args, PyObject *kwds);

static PyObject *
tuple_new(PyTypeObject *type, PyObject *args, PyObject *kwds)
{
	PyObject *arg = NULL;
	static char *kwlist[] = {"sequence", 0};

	if (type != &PyTuple_Type)
		return tuple_subtype_new(type, args, kwds);
	if (!PyArg_ParseTupleAndKeywords(args, kwds, "|O:tuple", kwlist, &arg))
		return NULL;

	if (arg == NULL)
		return PyTuple_New(0);
	else
		return PySequence_Tuple(arg);
}

static PyObject *
tuple_subtype_new(PyTypeObject *type, PyObject *args, PyObject *kwds)
{
	PyObject *tmp, *new, *item;
	int i, n;

	assert(PyType_IsSubtype(type, &PyTuple_Type));
	tmp = tuple_new(&PyTuple_Type, args, kwds);
	if (tmp == NULL)
		return NULL;
	assert(PyTuple_Check(tmp));
	new = type->tp_alloc(type, n = PyTuple_GET_SIZE(tmp));
	if (new == NULL)
		return NULL;
	for (i = 0; i < n; i++) {
		item = PyTuple_GET_ITEM(tmp, i);
		Py_INCREF(item);
		PyTuple_SET_ITEM(new, i, item);
	}
	Py_DECREF(tmp);
	return new;
}

static char tuple_doc[] =
"tuple(sequence) -> list\n\
\n\
Return a tuple whose items are the same as those of the argument sequence.\n\
If the argument is a tuple, the return value is the same object.";

static PySequenceMethods tuple_as_sequence = {
	(inquiry)tuplelength,			/* sq_length */
	(binaryfunc)tupleconcat,		/* sq_concat */
	(intargfunc)tuplerepeat,		/* sq_repeat */
	(intargfunc)tupleitem,			/* sq_item */
	(intintargfunc)tupleslice,		/* sq_slice */
	0,					/* sq_ass_item */
	0,					/* sq_ass_slice */
	(objobjproc)tuplecontains,		/* sq_contains */
};

PyTypeObject PyTuple_Type = {
	PyObject_HEAD_INIT(&PyType_Type)
	0,
	"tuple",
	sizeof(PyTupleObject) - sizeof(PyObject *),
	sizeof(PyObject *),
	(destructor)tupledealloc,		/* tp_dealloc */
	(printfunc)tupleprint,			/* tp_print */
	0,					/* tp_getattr */
	0,					/* tp_setattr */
	0,					/* tp_compare */
	(reprfunc)tuplerepr,			/* tp_repr */
	0,					/* tp_as_number */
	&tuple_as_sequence,			/* tp_as_sequence */
	0,					/* tp_as_mapping */
	(hashfunc)tuplehash,			/* tp_hash */
	0,					/* tp_call */
	0,					/* tp_str */
	PyObject_GenericGetAttr,		/* tp_getattro */
	0,					/* tp_setattro */
	0,					/* tp_as_buffer */
	Py_TPFLAGS_DEFAULT | Py_TPFLAGS_HAVE_GC |
		Py_TPFLAGS_BASETYPE,		/* tp_flags */
	tuple_doc,				/* tp_doc */
 	(traverseproc)tupletraverse,		/* tp_traverse */
	0,					/* tp_clear */
	tuplerichcompare,			/* tp_richcompare */
	0,					/* tp_weaklistoffset */
	0,					/* tp_iter */
	0,					/* tp_iternext */
	0,					/* tp_methods */
	0,					/* tp_members */
	0,					/* tp_getset */
	0,					/* tp_base */
	0,					/* tp_dict */
	0,					/* tp_descr_get */
	0,					/* tp_descr_set */
	0,					/* tp_dictoffset */
	0,					/* tp_init */
	0,					/* tp_alloc */
	tuple_new,				/* tp_new */
};

/* The following function breaks the notion that tuples are immutable:
   it changes the size of a tuple.  We get away with this only if there
   is only one module referencing the object.  You can also think of it
   as creating a new tuple object and destroying the old one, only more
   efficiently.  In any case, don't use this if the tuple may already be
   known to some other part of the code. */

int
_PyTuple_Resize(PyObject **pv, int newsize)
{
	register PyTupleObject *v;
	register PyTupleObject *sv;
	int i;
	int sizediff;

	v = (PyTupleObject *) *pv;
	if (v == NULL || v->ob_type != &PyTuple_Type ||
	    (v->ob_size != 0 && v->ob_refcnt != 1)) {
		*pv = 0;
		Py_XDECREF(v);
		PyErr_BadInternalCall();
		return -1;
	}
	sizediff = newsize - v->ob_size;
	if (sizediff == 0)
		return 0;

	if (v->ob_size == 0) {
		/* Empty tuples are often shared, so we should never 
		   resize them in-place even if we do own the only
		   (current) reference */
		Py_DECREF(v);
		*pv = PyTuple_New(newsize);
		return *pv == NULL ? -1 : 0;
	}

	/* XXX UNREF/NEWREF interface should be more symmetrical */
#ifdef Py_REF_DEBUG
	--_Py_RefTotal;
#endif
	_PyObject_GC_UNTRACK(v);
	_Py_ForgetReference((PyObject *) v);
	for (i = newsize; i < v->ob_size; i++) {
		Py_XDECREF(v->ob_item[i]);
		v->ob_item[i] = NULL;
	}
	sv = PyObject_GC_Resize(PyTupleObject, v, newsize);
	if (sv == NULL) {
		*pv = NULL;
		PyObject_GC_Del(v);
		return -1;
	}
	_Py_NewReference((PyObject *) sv);
	for (i = sv->ob_size; i < newsize; i++)
		sv->ob_item[i] = NULL;
	*pv = (PyObject *) sv;
	_PyObject_GC_TRACK(sv);
	return 0;
}

void
PyTuple_Fini(void)
{
#if MAXSAVESIZE > 0
	int i;

	Py_XDECREF(free_tuples[0]);
	free_tuples[0] = NULL;

	for (i = 1; i < MAXSAVESIZE; i++) {
		PyTupleObject *p, *q;
		p = free_tuples[i];
		free_tuples[i] = NULL;
		while (p) {
			q = p;
			p = (PyTupleObject *)(p->ob_item[0]);
			PyObject_GC_Del(q);
		}
	}
#endif
}
/*
 * tclUtil.c --
 *
 *	This file contains utility functions that are used by many Tcl
 *	commands.
 *
 * Copyright (c) 1987-1993 The Regents of the University of California.
 * Copyright (c) 1994-1998 Sun Microsystems, Inc.
 * Copyright (c) 2001 by Kevin B. Kenny. All rights reserved.
 *
 * See the file "license.terms" for information on usage and redistribution of
 * this file, and for a DISCLAIMER OF ALL WARRANTIES.
 */

#include "tclInt.h"
#include <float.h>
#include <math.h>

/*
 * The absolute pathname of the executable in which this Tcl library is
 * running.
 */

static ProcessGlobalValue executableName = {
    0, 0, NULL, NULL, NULL, NULL, NULL
};

/*
 * The following values are used in the flags arguments of Tcl*Scan*Element and
 * Tcl*Convert*Element. The values TCL_DONT_USE_BRACES and TCL_DONT_QUOTE_HASH
 * are defined in tcl.h, like so:
 *
#define TCL_DONT_USE_BRACES     1
#define TCL_DONT_QUOTE_HASH     8
 *
 * Those are public flag bits which callers of the public routines
 * Tcl_Convert*Element() can use to indicate:
 *
 * TCL_DONT_USE_BRACES -	1 means the caller is insisting that brace
 *				quoting not be used when converting the list
 *				element.
 * TCL_DONT_QUOTE_HASH -	1 means the caller insists that a leading hash
 * 				character ('#') should *not* be quoted. This
 * 				is appropriate when the caller can guarantee
 * 				the element is not the first element of a
 * 				list, so [eval] cannot mis-parse the element
 * 				as a comment.
 *
 * The remaining values which can be carried by the flags of these routines
 * are for internal use only.  Make sure they do not overlap with the public
 * values above.
 *
 * The Tcl*Scan*Element() routines make a determination which of 4 modes of
 * conversion is most appropriate for Tcl*Convert*Element() to perform, and
 * sets two bits of the flags value to indicate the mode selected.
 *
 * CONVERT_NONE		The element needs no quoting.  Its literal string
 *			is suitable as is.
 * CONVERT_BRACE	The conversion should be enclosing the literal string
 *			in braces.
 * CONVERT_ESCAPE	The conversion should be using backslashes to escape
 *			any characters in the string that require it.
 * CONVERT_MASK		A mask value used to extract the conversion mode from
 *			the flags argument.
 *			Also indicates a strange conversion mode where all
 *			special characters are escaped with backslashes
 *			*except for braces*.  This is a strange and unnecessary
 *			case, but it's part of the historical way in which
 *			lists have been formatted in Tcl.  To experiment with
 *			removing this case, set the value of COMPAT to 0.
 *
 * One last flag value is used only by callers of TclScanElement().  The flag
 * value produced by a call to Tcl*Scan*Element() will never leave this bit
 * set.
 *
 * CONVERT_ANY		The caller of TclScanElement() declares it can make
 *			no promise about what public flags will be passed to
 *			the matching call of TclConvertElement().  As such,
 *			TclScanElement() has to determine the worst case
 *			destination buffer length over all possibilities, and
 *			in other cases this means an overestimate of the
 *			required size.
 *
 * For more details, see the comments on the Tcl*Scan*Element and
 * Tcl*Convert*Element routines.
 */

#define COMPAT 1
#define CONVERT_NONE	0
#define CONVERT_BRACE	2
#define CONVERT_ESCAPE	4
#define CONVERT_MASK	(CONVERT_BRACE | CONVERT_ESCAPE)
#define CONVERT_ANY	16

/*
 * The following key is used by Tcl_PrintDouble and TclPrecTraceProc to
 * access the precision to be used for double formatting.
 */

static Tcl_ThreadDataKey precisionKey;

/*
 * Prototypes for functions defined later in this file.
 */

static void		ClearHash(Tcl_HashTable *tablePtr);
static void		FreeProcessGlobalValue(ClientData clientData);
static void		FreeThreadHash(ClientData clientData);
static Tcl_HashTable *	GetThreadHash(Tcl_ThreadDataKey *keyPtr);
static int		SetEndOffsetFromAny(Tcl_Interp* interp,
			    Tcl_Obj* objPtr);
static void		UpdateStringOfEndOffset(Tcl_Obj* objPtr);

/*
 * The following is the Tcl object type definition for an object that
 * represents a list index in the form, "end-offset". It is used as a
 * performance optimization in TclGetIntForIndex. The internal rep is an
 * integer, so no memory management is required for it.
 */

Tcl_ObjType tclEndOffsetType = {
    "end-offset",			/* name */
    NULL,				/* freeIntRepProc */
    NULL,				/* dupIntRepProc */
    UpdateStringOfEndOffset,		/* updateStringProc */
    SetEndOffsetFromAny
};

/*
 *	*	STRING REPRESENTATION OF LISTS	*	*	*
 *
 * The next several routines implement the conversions of strings to and
 * from Tcl lists.  To understand their operation, the rules of parsing
 * and generating the string representation of lists must be known.  Here
 * we describe them in one place.
 *
 * A list is made up of zero or more elements.  Any string is a list if
 * it is made up of alternating substrings of element-separating ASCII
 * whitespace and properly formatted elements.
 *
 * The ASCII characters which can make up the whitespace between list
 * elements are:
 *
 *	\u0009	\t	TAB
 *	\u000A	\n	NEWLINE
 *	\u000B	\v	VERTICAL TAB
 *	\u000C	\f	FORM FEED
 * 	\u000D	\r	CARRIAGE RETURN
 *	\u0020		SPACE
 *
 * NOTE: differences between this and other places where Tcl defines a role
 * for "whitespace".
 *
 *	* Unlike command parsing, here NEWLINE is just another whitespace
 *	  character; its role as a command terminator in a script has no
 *	  importance here.
 *
 *	* Unlike command parsing, the BACKSLASH NEWLINE sequence is not
 *	  considered to be a whitespace character.
 *
 *	* Other Unicode whitespace characters (recognized by
 *	  [string is space] or Tcl_UniCharIsSpace()) do not play any role
 *	  as element separators in Tcl lists.
 *
 *	* The NUL byte ought not appear, as it is not in strings properly
 *	  encoded for Tcl, but if it is present, it is not treated as
 *	  separating whitespace, or a string terminator.  It is just
 *	  another character in a list element.
 *
 * The interpretation of a formatted substring as a list element follows
 * rules similar to the parsing of the words of a command in a Tcl script.
 * Backslash substitution plays a key role, and is defined exactly as it is
 * in command parsing.  The same routine, TclParseBackslash() is used in both
 * command parsing and list parsing.
 *
 * NOTE:  This means that if and when backslash substitution rules ever
 * change for command parsing, the interpretation of strings as lists also
 * changes.
 *
 * Backslash substitution replaces an "escape sequence" of one or more
 * characters starting with
 *		\u005c	\	BACKSLASH
 * with a single character.  The one character escape sequence case happens
 * only when BACKSLASH is the last character in the string.  In all other
 * cases, the escape sequence is at least two characters long.
 *
 * The formatted substrings are interpreted as element values according to
 * the following cases:
 *
 * * If the first character of a formatted substring is
 *		\u007b	{	OPEN BRACE
 *   then the end of the substring is the matching
 *		\u007d	}	CLOSE BRACE
 *   character, where matching is determined by counting nesting levels,
 *   and not including any brace characters that are contained within a
 *   backslash escape sequence in the nesting count.  Having found the
 *   matching brace, all characters between the braces are the string
 *   value of the element.  If no matching close brace is found before the
 *   end of the string, the string is not a Tcl list.  If the character
 *   following the close brace is not an element separating whitespace
 *   character, or the end of the string, then the string is not a Tcl list.
 *
 *   NOTE: this differs from a brace-quoted word in the parsing of a
 *   Tcl command only in its treatment of the backslash-newline sequence.
 *   In a list element, the literal characters in the backslash-newline
 *   sequence become part of the element value.  In a script word,
 *   conversion to a single SPACE character is done.
 *
 *   NOTE: Most list element values can be represented by a formatted
 *   substring using brace quoting.  The exceptions are any element value
 *   that includes an unbalanced brace not in a backslash escape sequence,
 *   and any value that ends with a backslash not itself in a backslash
 *   escape sequence.
 *
 * * If the first character of a formatted substring is
 *		\u0022	"	QUOTE
 *   then the end of the substring is the next QUOTE character, not counting
 *   any QUOTE characters that are contained within a backslash escape
 *   sequence.  If no next QUOTE is found before the end of the string, the
 *   string is not a Tcl list.  If the character following the closing QUOTE
 *   is not an element separating whitespace character, or the end of the
 *   string, then the string is not a Tcl list.  Having found the limits
 *   of the substring, the element value is produced by performing backslash
 *   substitution on the character sequence between the open and close QUOTEs.
 *
 *   NOTE: Any element value can be represented by this style of formatting,
 *   given suitable choice of backslash escape sequences.
 *
 * * All other formatted substrings are terminated by the next element
 *   separating whitespace character in the string.  Having found the limits
 *   of the substring, the element value is produced by performing backslash
 *   substitution on it.
 *
 *   NOTE:  Any element value can be represented by this style of formatting,
 *   given suitable choice of backslash escape sequences, with one exception.
 *   The empty string cannot be represented as a list element without the use
 *   of either braces or quotes to delimit it.
 *
 * This collection of parsing rules is implemented in the routine
 * TclFindElement().
 *
 * In order to produce lists that can be parsed by these rules, we need
 * the ability to distinguish between characters that are part of a list
 * element value from characters providing syntax that define the structure
 * of the list.  This means that our code that generates lists must at a
 * minimum be able to produce escape sequences for the 10 characters
 * identified above that have significance to a list parser.
 *
 *	*	*	CANONICAL LISTS	*	*	*	*	*
 *
 * In addition to the basic rules for parsing strings into Tcl lists, there
 * are additional properties to be met by the set of list values that are
 * generated by Tcl.  Such list values are often said to be in "canonical
 * form":
 *
 * * When any canonical list is evaluated as a Tcl script, it is a script
 *   of either zero commands (an empty list) or exactly one command.  The
 *   command word is exactly the first element of the list, and each argument
 *   word is exactly one of the following elements of the list.  This means
 *   that any characters that have special meaning during script evaluation
 *   need special treatment when canonical lists are produced:
 *
 *	* Whitespace between elements may not include NEWLINE.
 *	* The command terminating character,
 *		\u003b	;	SEMICOLON
 *	  must be BRACEd, QUOTEd, or escaped so that it does not terminate
 * 	  the command prematurely.
 *	* Any of the characters that begin substitutions in scripts,
 *		\u0024	$	DOLLAR
 *		\u005b	[	OPEN BRACKET
 *		\u005c	\	BACKSLASH
 *	  need to be BRACEd or escaped.
 *	* In any list where the first character of the first element is
 *		\u0023	#	HASH
 *	  that HASH character must be BRACEd, QUOTEd, or escaped so that it
 *	  does not convert the command into a comment.
 *	* Any list element that contains the character sequence
 *	  BACKSLASH NEWLINE cannot be formatted with BRACEs.  The
 *	  BACKSLASH character must be represented by an escape
 *	  sequence, and unless QUOTEs are used, the NEWLINE must
 *	  be as well.
 *
 * * It is also guaranteed that one can use a canonical list as a building
 *   block of a larger script within command substitution, as in this example:
 *	set script "puts \[[list $cmd $arg]]"; eval $script
 *   To support this usage, any appearance of the character
 *		\u005d	]	CLOSE BRACKET
 *   in a list element must be BRACEd, QUOTEd, or escaped.
 *
 * * Finally it is guaranteed that enclosing a canonical list in braces
 *   produces a new value that is also a canonical list.  This new list has
 *   length 1, and its only element is the original canonical list.  This
 *   same guarantee also makes it possible to construct scripts where an
 *   argument word is given a list value by enclosing the canonical form
 *   of that list in braces:
 *	set script "puts {[list $one $two $three]}"; eval $script
 *   This sort of coding was once fairly common, though it's become more
 *   idiomatic to see the following instead:
 *	set script [list puts [list $one $two $three]]; eval $script
 *   In order to support this guarantee, every canonical list must have
 *   balance when counting those braces that are not in escape sequences.
 *
 * Within these constraints, the canonical list generation routines
 * TclScanElement() and TclConvertElement() attempt to generate the string
 * for any list that is easiest to read.  When an element value is itself
 * acceptable as the formatted substring, it is usually used (CONVERT_NONE).
 * When some quoting or escaping is required, use of BRACEs (CONVERT_BRACE)
 * is usually preferred over the use of escape sequences (CONVERT_ESCAPE).
 * There are some exceptions to both of these preferences for reasons of
 * code simplicity, efficiency, and continuation of historical habits.
 * Canonical lists never use the QUOTE formatting to delimit their elements
 * because that form of quoting does not nest, which makes construction of
 * nested lists far too much trouble.  Canonical lists always use only a
 * single SPACE character for element-separating whitespace.
 *
 *	*	*	FUTURE CONSIDERATIONS	*	*	*
 *
 * When a list element requires quoting or escaping due to a CLOSE BRACKET
 * character or an internal QUOTE character, a strange formatting mode is
 * recommended.  For example, if the value "a{b]c}d" is converted by the
 * usual modes:
 *
 *	CONVERT_BRACE:	a{b]c}d		=> {a{b]c}d}
 *	CONVERT_ESCAPE:	a{b]c}d		=> a\{b\]c\}d
 *
 * we get perfectly usable formatted list elements.  However, this is not
 * what Tcl releases have been producing.  Instead, we have:
 *
 *	CONVERT_MASK:	a{b]c}d		=> a{b\]c}d
 *
 * where the CLOSE BRACKET is escaped, but the BRACEs are not.  The same
 * effect can be seen replacing ] with " in this example.  There does not
 * appear to be any functional or aesthetic purpose for this strange
 * additional mode.  The sole purpose I can see for preserving it is to
 * keep generating the same formatted lists programmers have become accustomed
 * to, and perhaps written tests to expect.  That is, compatibility only.
 * The additional code complexity required to support this mode is significant.
 * The lines of code supporting it are delimited in the routines below with
 * #if COMPAT directives.  This makes it easy to experiment with eliminating
 * this formatting mode simply with "#define COMPAT 0" above.  I believe
 * this is worth considering.
 *
 * Another consideration is the treatment of QUOTE characters in list elements.
 * TclConvertElement() must have the ability to produce the escape sequence
 * \" so that when a list element begins with a QUOTE we do not confuse
 * that first character with a QUOTE used as list syntax to define list
 * structure.  However, that is the only place where QUOTE characters need
 * quoting.  In this way, handling QUOTE could really be much more like
 * the way we handle HASH which also needs quoting and escaping only in
 * particular situations.  Following up this could increase the set of
 * list elements that can use the CONVERT_NONE formatting mode.
 *
 * More speculative is that the demands of canonical list form require brace
 * balance for the list as a whole, while the current implementation achieves
 * this by establishing brace balance for every element.
 *
 * Finally, a reminder that the rules for parsing and formatting lists are
 * closely tied together with the rules for parsing and evaluating scripts,
 * and will need to evolve in sync.
 */

/*
 *----------------------------------------------------------------------
 *
 * TclMaxListLength --
 *
 *	Given 'bytes' pointing to 'numBytes' bytes, scan through them and
 *	count the number of whitespace runs that could be list element
 *	separators.  If 'numBytes' is -1, scan to the terminating '\0'.
 *	Not a full list parser.  Typically used to get a quick and dirty
 *	overestimate of length size in order to allocate space for an
 *	actual list parser to operate with.
 *
 * Results:
 *	Returns the largest number of list elements that could possibly
 *	be in this string, interpreted as a Tcl list.  If 'endPtr' is not
 *	NULL, writes a pointer to the end of the string scanned there.
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

int
TclMaxListLength(
    CONST char *bytes,
    int numBytes,
    CONST char **endPtr)
{
    int count = 0;

    if ((numBytes == 0) || ((numBytes == -1) && (*bytes == '\0'))) {
	/* Empty string case - quick exit */
	goto done;
    }

    /* No list element before leading white space */
    count += 1 - TclIsSpaceProc(*bytes);

    /* Count white space runs as potential element separators */
    while (numBytes) {
	if ((numBytes == -1) && (*bytes == '\0')) {
	    break;
	}
	if (TclIsSpaceProc(*bytes)) {
	    /* Space run started; bump count */
	    count++;
	    do {
		bytes++;
		numBytes -= (numBytes != -1);
	    } while (numBytes && TclIsSpaceProc(*bytes));
	    if ((numBytes == 0) || ((numBytes == -1) && (*bytes == '\0'))) {
		break;
	    }
	    /* (*bytes) is non-space; return to counting state */
	}
	bytes++;
	numBytes -= (numBytes != -1);
    }

    /* No list element following trailing white space */
    count -= TclIsSpaceProc(bytes[-1]);

    done:
    if (endPtr) {
	*endPtr = bytes;
    }
    return count;
}

/*
 *----------------------------------------------------------------------
 *
 * TclFindElement --
 *
 *	Given a pointer into a Tcl list, locate the first (or next) element in
 *	the list.
 *
 * Results:
 *	The return value is normally TCL_OK, which means that the element was
 *	successfully located. If TCL_ERROR is returned it means that list
 *	didn't have proper list structure; the interp's result contains a more
 *	detailed error message.
 *
 *	If TCL_OK is returned, then *elementPtr will be set to point to the
 *	first element of list, and *nextPtr will be set to point to the
 *	character just after any white space following the last character
 *	that's part of the element. If this is the last argument in the list,
 *	then *nextPtr will point just after the last character in the list
 *	(i.e., at the character at list+listLength). If sizePtr is non-NULL,
 *	*sizePtr is filled in with the number of bytes in the element. If
 *	the element is in braces, then *elementPtr will point to the character
 *	after the opening brace and *sizePtr will not include either of the
 *	braces. If there isn't an element in the list, *sizePtr will be zero,
 *	and both *elementPtr and *nextPtr will point just after the last
 *	character in the list. If literalPtr is non-NULL, *literalPtr is set
 *	to a boolean value indicating whether the substring returned as
 *	the values of **elementPtr and *sizePtr is the literal value of
 *	a list element.  If not, a call to TclCopyAndCollapse() is needed
 *	to produce the actual value of the list element.  Note: this function
 *	does NOT collapse backslash sequences, but uses *literalPtr to tell
 * 	callers when it is required for them to do so.
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

int
TclFindElement(
    Tcl_Interp *interp,		/* Interpreter to use for error reporting. If
				 * NULL, then no error message is left after
				 * errors. */
    CONST char *list,		/* Points to the first byte of a string
				 * containing a Tcl list with zero or more
				 * elements (possibly in braces). */
    int listLength,		/* Number of bytes in the list's string. */
    CONST char **elementPtr,	/* Where to put address of first significant
				 * character in first element of list. */
    CONST char **nextPtr,	/* Fill in with location of character just
				 * after all white space following end of
				 * argument (next arg or end of list). */
    int *sizePtr,		/* If non-zero, fill in with size of
				 * element. */
    int *literalPtr)		/* If non-zero, fill in with non-zero/zero to
				 * indicate that the substring of *sizePtr
				 * bytes starting at **elementPtr is/is not
				 * the literal list element and therefore
				 * does not/does require a call to
				 * TclCopyAndCollapse() by the caller. */
{
    CONST char *p = list;
    CONST char *elemStart;	/* Points to first byte of first element. */
    CONST char *limit;		/* Points just after list's last byte. */
    int openBraces = 0;		/* Brace nesting level during parse. */
    int inQuotes = 0;
    int size = 0;		/* lint. */
    int numChars;
    int literal = 1;
    CONST char *p2;

    /*
     * Skim off leading white space and check for an opening brace or quote.
     * We treat embedded NULLs in the list as bytes belonging to a list
     * element.
     */

    limit = (list + listLength);
    while ((p < limit) && (TclIsSpaceProc(*p))) {
	p++;
    }
    if (p == limit) {		/* no element found */
	elemStart = limit;
	goto done;
    }

    if (*p == '{') {
	openBraces = 1;
	p++;
    } else if (*p == '"') {
	inQuotes = 1;
	p++;
    }
    elemStart = p;

    /*
     * Find element's end (a space, close brace, or the end of the string).
     */

    while (p < limit) {
	switch (*p) {
	    /*
	     * Open brace: don't treat specially unless the element is in
	     * braces. In this case, keep a nesting count.
	     */

	case '{':
	    if (openBraces != 0) {
		openBraces++;
	    }
	    break;

	    /*
	     * Close brace: if element is in braces, keep nesting count and
	     * quit when the last close brace is seen.
	     */

	case '}':
	    if (openBraces > 1) {
		openBraces--;
	    } else if (openBraces == 1) {
		size = (p - elemStart);
		p++;
		if ((p >= limit) || TclIsSpaceProc(*p)) {
		    goto done;
		}

		/*
		 * Garbage after the closing brace; return an error.
		 */

		if (interp != NULL) {
		    p2 = p;
		    while ((p2 < limit) && (!TclIsSpaceProc(*p2))
			    && (p2 < p+20)) {
			p2++;
		    }
		    Tcl_SetObjResult(interp, Tcl_ObjPrintf(
			    "list element in braces followed by \"%.*s\" "
			    "instead of space", (int) (p2-p), p));
		}
		return TCL_ERROR;
	    }
	    break;

	    /*
	     * Backslash: skip over everything up to the end of the backslash
	     * sequence.
	     */

	case '\\':
	    if (openBraces == 0) {
		/*
		 * A backslash sequence not within a brace quoted element
		 * means the value of the element is different from the
		 * substring we are parsing.  A call to TclCopyAndCollapse()
		 * is needed to produce the element value.  Inform the caller.
		 */
		literal = 0;
	    }
	    TclParseBackslash(p, limit - p, &numChars, NULL);
	    p += (numChars - 1);
	    break;

	    /*
	     * Space: ignore if element is in braces or quotes; otherwise
	     * terminate element.
	     */

	case ' ':
	case '\f':
	case '\n':
	case '\r':
	case '\t':
	case '\v':
	    if ((openBraces == 0) && !inQuotes) {
		size = (p - elemStart);
		goto done;
	    }
	    break;

	    /*
	     * Double-quote: if element is in quotes then terminate it.
	     */

	case '"':
	    if (inQuotes) {
		size = (p - elemStart);
		p++;
		if ((p >= limit) || TclIsSpaceProc(*p)) {
		    goto done;
		}

		/*
		 * Garbage after the closing quote; return an error.
		 */

		if (interp != NULL) {
		    p2 = p;
		    while ((p2 < limit) && (!TclIsSpaceProc(*p2))
			    && (p2 < p+20)) {
			p2++;
		    }
		    Tcl_SetObjResult(interp, Tcl_ObjPrintf(
			    "list element in quotes followed by \"%.*s\" "
			    "instead of space", (int) (p2-p), p));
		}
		return TCL_ERROR;
	    }
	    break;
	}
	p++;
    }

    /*
     * End of list: terminate element.
     */

    if (p == limit) {
	if (openBraces != 0) {
	    if (interp != NULL) {
		Tcl_SetResult(interp, "unmatched open brace in list",
			TCL_STATIC);
	    }
	    return TCL_ERROR;
	} else if (inQuotes) {
	    if (interp != NULL) {
		Tcl_SetResult(interp, "unmatched open quote in list",
			TCL_STATIC);
	    }
	    return TCL_ERROR;
	}
	size = (p - elemStart);
    }

  done:
    while ((p < limit) && (TclIsSpaceProc(*p))) {
	p++;
    }
    *elementPtr = elemStart;
    *nextPtr = p;
    if (sizePtr != 0) {
	*sizePtr = size;
    }
    if (literalPtr != 0) {
	*literalPtr = literal;
    }
    return TCL_OK;
}

/*
 *----------------------------------------------------------------------
 *
 * TclCopyAndCollapse --
 *
 *	Copy a string and substitute all backslash escape sequences
 *
 * Results:
 *	Count bytes get copied from src to dst. Along the way, backslash
 *	sequences are substituted in the copy.  After scanning count bytes
 *	from src, a null character is placed at the end of dst.  Returns
 *	the number of bytes that got written to dst.
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

int
TclCopyAndCollapse(
    int count,			/* Number of byte to copy from src. */
    CONST char *src,		/* Copy from here... */
    char *dst)			/* ... to here. */
{
    int newCount = 0;

    while (count > 0) {
	char c = *src;
	if (c == '\\') {
	    int numRead;
	    int backslashCount = TclParseBackslash(src, count, &numRead, dst);

	    dst += backslashCount;
	    newCount += backslashCount;
	    src += numRead;
	    count -= numRead;
	} else {
	    *dst = c;
	    dst++;
	    newCount++;
	    src++;
	    count--;
	}
    }
    *dst = 0;
    return newCount;
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_SplitList --
 *
 *	Splits a list up into its constituent fields.
 *
 * Results
 *	The return value is normally TCL_OK, which means that the list was
 *	successfully split up. If TCL_ERROR is returned, it means that "list"
 *	didn't have proper list structure; the interp's result will contain a
 *	more detailed error message.
 *
 *	*argvPtr will be filled in with the address of an array whose elements
 *	point to the elements of list, in order. *argcPtr will get filled in
 *	with the number of valid elements in the array. A single block of
 *	memory is dynamically allocated to hold both the argv array and a copy
 *	of the list (with backslashes and braces removed in the standard way).
 *	The caller must eventually free this memory by calling free() on
 *	*argvPtr. Note: *argvPtr and *argcPtr are only modified if the
 *	function returns normally.
 *
 * Side effects:
 *	Memory is allocated.
 *
 *----------------------------------------------------------------------
 */

int
Tcl_SplitList(
    Tcl_Interp *interp,		/* Interpreter to use for error reporting. If
				 * NULL, no error message is left. */
    CONST char *list,		/* Pointer to string with list structure. */
    int *argcPtr,		/* Pointer to location to fill in with the
				 * number of elements in the list. */
    CONST char ***argvPtr)	/* Pointer to place to store pointer to array
				 * of pointers to list elements. */
{
    CONST char **argv, *end, *element;
    char *p;
    int length, size, i, result, elSize;

    /*
     * Allocate enough space to work in. A (CONST char *) for each
     * (possible) list element plus one more for terminating NULL,
     * plus as many bytes as in the original string value, plus one
     * more for a terminating '\0'.  Space used to hold element separating
     * white space in the original string gets re-purposed to hold '\0'
     * characters in the argv array.
     */

    size = TclMaxListLength(list, -1, &end) + 1;
    length = end - list;
    argv = (CONST char **) ckalloc((unsigned)
	    ((size * sizeof(char *)) + length + 1));

    for (i = 0, p = ((char *) argv) + size*sizeof(char *);
	    *list != 0;  i++) {
	CONST char *prevList = list;
	int literal;

	result = TclFindElement(interp, list, length, &element, &list,
		&elSize, &literal);
	length -= (list - prevList);
	if (result != TCL_OK) {
	    ckfree((char *) argv);
	    return result;
	}
	if (*element == 0) {
	    break;
	}
	if (i >= size) {
	    ckfree((char *) argv);
	    if (interp != NULL) {
		Tcl_SetResult(interp, "internal error in Tcl_SplitList",
			TCL_STATIC);
	    }
	    return TCL_ERROR;
	}
	argv[i] = p;
	if (literal) {
	    memcpy(p, element, (size_t) elSize);
	    p += elSize;
	    *p = 0;
	    p++;
	} else {
	    p += 1 + TclCopyAndCollapse(elSize, element, p);
	}
    }

    argv[i] = NULL;
    *argvPtr = argv;
    *argcPtr = i;
    return TCL_OK;
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_ScanElement --
 *
 *	This function is a companion function to Tcl_ConvertElement. It scans
 *	a string to see what needs to be done to it (e.g. add backslashes or
 *	enclosing braces) to make the string into a valid Tcl list element.
 *
 * Results:
 *	The return value is an overestimate of the number of bytes that
 *	will be needed by Tcl_ConvertElement to produce a valid list element
 *	from src. The word at *flagPtr is filled in with a value needed by
 *	Tcl_ConvertElement when doing the actual conversion.
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

int
Tcl_ScanElement(
    register CONST char *src,	/* String to convert to list element. */
    register int *flagPtr)	/* Where to store information to guide
				 * Tcl_ConvertCountedElement. */
{
    return Tcl_ScanCountedElement(src, -1, flagPtr);
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_ScanCountedElement --
 *
 *	This function is a companion function to Tcl_ConvertCountedElement. It
 *	scans a string to see what needs to be done to it (e.g. add
 *	backslashes or enclosing braces) to make the string into a valid Tcl
 *	list element. If length is -1, then the string is scanned from src up
 *	to the first null byte.
 *
 * Results:
 *	The return value is an overestimate of the number of bytes that
 *	will be needed by Tcl_ConvertCountedElement to produce a valid list
 *	element from src. The word at *flagPtr is filled in with a value
 *	needed by Tcl_ConvertCountedElement when doing the actual conversion.
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

int
Tcl_ScanCountedElement(
    CONST char *src,		/* String to convert to Tcl list element. */
    int length,			/* Number of bytes in src, or -1. */
    int *flagPtr)		/* Where to store information to guide
				 * Tcl_ConvertElement. */
{
    int flags = CONVERT_ANY;
    int numBytes = TclScanElement(src, length, &flags);

    *flagPtr = flags;
    return numBytes;
}

/*
 *----------------------------------------------------------------------
 *
 * TclScanElement --
 *
 *	This function is a companion function to TclConvertElement. It
 *	scans a string to see what needs to be done to it (e.g. add
 *	backslashes or enclosing braces) to make the string into a valid Tcl
 *	list element. If length is -1, then the string is scanned from src up
 *	to the first null byte.  A NULL value for src is treated as an
 *	empty string.  The incoming value of *flagPtr is a report from the
 *	caller what additional flags it will pass to TclConvertElement().
 *
 * Results:
 *	The recommended formatting mode for the element is determined and
 *	a value is written to *flagPtr indicating that recommendation.  This
 *	recommendation is combined with the incoming flag values in *flagPtr
 *	set by the caller to determine how many bytes will be needed by
 *	TclConvertElement() in which to write the formatted element following
 *	the recommendation modified by the flag values.  This number of bytes
 *	is the return value of the routine.  In some situations it may be
 *	an overestimate, but so long as the caller passes the same flags
 *	to TclConvertElement(), it will be large enough.
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

int
TclScanElement(
    CONST char *src,		/* String to convert to Tcl list element. */
    int length,			/* Number of bytes in src, or -1. */
    int *flagPtr)		/* Where to store information to guide
				 * Tcl_ConvertElement. */
{
    CONST char *p = src;
    int nestingLevel = 0;	/* Brace nesting count */
    int forbidNone = 0;		/* Do not permit CONVERT_NONE mode. Something
				   needs protection or escape. */
    int requireEscape = 0;	/* Force use of CONVERT_ESCAPE mode.  For some
				 * reason bare or brace-quoted form fails. */
    int extra = 0;		/* Count of number of extra bytes needed for
				 * formatted element, assuming we use escape
				 * sequences in formatting. */
    int bytesNeeded;		/* Buffer length computed to complete the
				 * element formatting in the selected mode. */
#if COMPAT
    int preferEscape = 0;	/* Use preferences to track whether to use */
    int preferBrace = 0;	/* CONVERT_MASK mode. */
    int braceCount = 0;		/* Count of all braces '{' '}' seen. */
#endif

    if ((p == NULL) || (length == 0) || ((*p == '\0') && (length == -1))) {
	/* Empty string element must be brace quoted. */
	*flagPtr = CONVERT_BRACE;
	return 2;
    }

    if ((*p == '{') || (*p == '"')) {
	/*
	 * Must escape or protect so leading character of value is not
	 * misinterpreted as list element delimiting syntax.
	 */
	forbidNone = 1;
#if COMPAT
	preferBrace = 1;
#endif
    }

    while (length) {
	switch (*p) {
	case '{':
#if COMPAT
	    braceCount++;
#endif
	    extra++;				/* Escape '{' => '\{' */
	    nestingLevel++;
	    break;
	case '}':
#if COMPAT
	    braceCount++;
#endif
	    extra++;				/* Escape '}' => '\}' */
	    nestingLevel--;
	    if (nestingLevel < 0) {
		/* Unbalanced braces!  Cannot format with brace quoting. */
		requireEscape = 1;
	    }
	    break;
	case ']':
	case '"':
#if COMPAT
	    forbidNone = 1;
	    extra++;		/* Escapes all just prepend a backslash */
	    preferEscape = 1;
	    break;
#else
	    /* FLOW THROUGH */
#endif
	case '[':
	case '$':
	case ';':
	case ' ':
	case '\f':
	case '\n':
	case '\r':
	case '\t':
	case '\v':
	    forbidNone = 1;
	    extra++;		/* Escape sequences all one byte longer. */
#if COMPAT
	    preferBrace = 1;
#endif
	    break;
	case '\\':
	    extra++;				/* Escape '\' => '\\' */
	    if ((length == 1) || ((length == -1) && (p[1] == '\0'))) {
		/* Final backslash. Cannot format with brace quoting. */
		requireEscape = 1;
		break;
	    }
	    if (p[1] == '\n') {
		extra++;	/* Escape newline => '\n', one byte longer */
		/* Backslash newline sequence.  Brace quoting not permitted. */
		requireEscape = 1;
		length -= (length > 0);
		p++;
		break;
	    }
	    if ((p[1] == '{') || (p[1] == '}') || (p[1] == '\\')) {
		extra++;	/* Escape sequences all one byte longer. */
		length -= (length > 0);
		p++;
	    }
	    forbidNone = 1;
#if COMPAT
	    preferBrace = 1;
#endif
	    break;
	case '\0':
	    if (length == -1) {
		goto endOfString;
	    }
	    /* TODO: Panic on improper encoding? */
	    break;
	}
	length -= (length > 0);
	p++;
    }

    endOfString:
    if (nestingLevel != 0) {
	/* Unbalanced braces!  Cannot format with brace quoting. */
	requireEscape = 1;
    }

    /* We need at least as many bytes as are in the element value... */
    bytesNeeded = p - src;

    if (requireEscape) {
	/*
	 * We must use escape sequences.  Add all the extra bytes needed
	 * to have room to create them.
	 */
	bytesNeeded += extra;
	/* Make room to escape leading #, if needed. */
	if ((*src == '#') && !(*flagPtr & TCL_DONT_QUOTE_HASH)) {
	    bytesNeeded++;
	}
	*flagPtr = CONVERT_ESCAPE;
	goto overflowCheck;
    }
    if (*flagPtr & CONVERT_ANY) {
	/*
	 * The caller has not let us know what flags it will pass to
	 * TclConvertElement() so compute the max size we might need for
	 * any possible choice.  Normally the formatting using escape
	 * sequences is the longer one, and a minimum "extra" value of 2
	 * makes sure we don't request too small a buffer in those edge
	 * cases where that's not true.
	 */
	if (extra < 2) {
	    extra = 2;
	}
	*flagPtr &= ~CONVERT_ANY;
	*flagPtr |= TCL_DONT_USE_BRACES;
    }
    if (forbidNone) {
	/* We must request some form of quoting of escaping... */
#if COMPAT
	if (preferEscape && !preferBrace) {
	    /*
	     * If we are quoting solely due to ] or internal " characters
	     * use the CONVERT_MASK mode where we escape all special
	     * characters except for braces.  "extra" counted space needed
	     * to escape braces too, so substract "braceCount" to get our
	     * actual needs.
	     */
	    bytesNeeded += (extra - braceCount);
	    /* Make room to escape leading #, if needed. */
	    if ((*src == '#') && !(*flagPtr & TCL_DONT_QUOTE_HASH)) {
		bytesNeeded++;
	    }
	    /*
	     * If the caller reports it will direct TclConvertElement() to
	     * use full escapes on the element, add back the bytes needed to
	     * escape the braces.
	     */
	    if (*flagPtr & TCL_DONT_USE_BRACES) {
		bytesNeeded += braceCount;
	    }
	    *flagPtr = CONVERT_MASK;
	    goto overflowCheck;
	}
#endif
	if (*flagPtr & TCL_DONT_USE_BRACES) {
	    /*
	     * If the caller reports it will direct TclConvertElement() to
	     * use escapes, add the extra bytes needed to have room for them.
	     */
	    bytesNeeded += extra;
	    /* Make room to escape leading #, if needed. */
	    if ((*src == '#') && !(*flagPtr & TCL_DONT_QUOTE_HASH)) {
		bytesNeeded++;
	    }
	} else {
	    /* Add 2 bytes for room for the enclosing braces. */
	    bytesNeeded += 2;
	}
	*flagPtr = CONVERT_BRACE;
	goto overflowCheck;
    }

    /* So far, no need to quote or escape anything. */
    if ((*src == '#') && !(*flagPtr & TCL_DONT_QUOTE_HASH)) {
	/* If we need to quote a leading #, make room to enclose in braces. */
	bytesNeeded += 2;
    }
    *flagPtr = CONVERT_NONE;

    overflowCheck:
    if (bytesNeeded < 0) {
	Tcl_Panic("TclScanElement: string length overflow");
    }
    return bytesNeeded;
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_ConvertElement --
 *
 *	This is a companion function to Tcl_ScanElement. Given the information
 *	produced by Tcl_ScanElement, this function converts a string to a list
 *	element equal to that string.
 *
 * Results:
 *	Information is copied to *dst in the form of a list element identical
 *	to src (i.e. if Tcl_SplitList is applied to dst it will produce a
 *	string identical to src). The return value is a count of the number of
 *	characters copied (not including the terminating NULL character).
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

int
Tcl_ConvertElement(
    register CONST char *src,	/* Source information for list element. */
    register char *dst,		/* Place to put list-ified element. */
    register int flags)		/* Flags produced by Tcl_ScanElement. */
{
    return Tcl_ConvertCountedElement(src, -1, dst, flags);
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_ConvertCountedElement --
 *
 *	This is a companion function to Tcl_ScanCountedElement. Given the
 *	information produced by Tcl_ScanCountedElement, this function converts
 *	a string to a list element equal to that string.
 *
 * Results:
 *	Information is copied to *dst in the form of a list element identical
 *	to src (i.e. if Tcl_SplitList is applied to dst it will produce a
 *	string identical to src). The return value is a count of the number of
 *	characters copied (not including the terminating NULL character).
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

int
Tcl_ConvertCountedElement(
    register CONST char *src,	/* Source information for list element. */
    int length,			/* Number of bytes in src, or -1. */
    char *dst,			/* Place to put list-ified element. */
    int flags)			/* Flags produced by Tcl_ScanElement. */
{
    int numBytes = TclConvertElement(src, length, dst, flags);
    dst[numBytes] = '\0';
    return numBytes;
}

/*
 *----------------------------------------------------------------------
 *
 * TclConvertElement --
 *
 *	This is a companion function to TclScanElement. Given the
 *	information produced by TclScanElement, this function converts
 *	a string to a list element equal to that string.
 *
 * Results:
 *	Information is copied to *dst in the form of a list element identical
 *	to src (i.e. if Tcl_SplitList is applied to dst it will produce a
 *	string identical to src). The return value is a count of the number of
 *	characters copied (not including the terminating NULL character).
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

int TclConvertElement(
    register CONST char *src,	/* Source information for list element. */
    int length,			/* Number of bytes in src, or -1. */
    char *dst,			/* Place to put list-ified element. */
    int flags)			/* Flags produced by Tcl_ScanElement. */
{
    int conversion = flags & CONVERT_MASK;
    char *p = dst;

    /* Let the caller demand we use escape sequences rather than braces. */
    if ((flags & TCL_DONT_USE_BRACES) && (conversion & CONVERT_BRACE)) {
	conversion = CONVERT_ESCAPE;
    }

    /* No matter what the caller demands, empty string must be braced! */
    if ((src == NULL) || (length == 0) || ((*src == '\0') && (length == -1))) {
	src = tclEmptyStringRep;
	length = 0;
	conversion = CONVERT_BRACE;
    }

    /* Escape leading hash as needed and requested. */
    if ((*src == '#') && !(flags & TCL_DONT_QUOTE_HASH)) {
	if (conversion == CONVERT_ESCAPE) {
	    p[0] = '\\';
	    p[1] = '#';
	    p += 2;
	    src++;
	    length -= (length > 0);
	} else {
	    conversion = CONVERT_BRACE;
	}
    }

    /* No escape or quoting needed.  Copy the literal string value. */
    if (conversion == CONVERT_NONE) {
	if (length == -1) {
	    /* TODO: INT_MAX overflow? */
	    while (*src) {
		*p++ = *src++;
	    }
	    return p - dst;
	} else {
	    memcpy(dst, src, length);
	    return length;
	}
    }

    /* Formatted string is original string enclosed in braces. */
    if (conversion == CONVERT_BRACE) {
	*p = '{';
	p++;
	if (length == -1) {
	    /* TODO: INT_MAX overflow? */
	    while (*src) {
		*p++ = *src++;
	    }
	} else {
	    memcpy(p, src, length);
	    p += length;
	}
	*p = '}';
	p++;
	return p - dst;
    }

    /* conversion == CONVERT_ESCAPE or CONVERT_MASK */

    /* Formatted string is original string converted to escape sequences. */
    for ( ; length; src++, length -= (length > 0)) {
	switch (*src) {
	case ']':
	case '[':
	case '$':
	case ';':
	case ' ':
	case '\\':
	case '"':
	    *p = '\\';
	    p++;
	    break;
	case '{':
	case '}':
#if COMPAT
	    if (conversion == CONVERT_ESCAPE) {
#endif
		*p = '\\';
		p++;
#if COMPAT
	    }
#endif
	    break;
	case '\f':
	    *p = '\\';
	    p++;
	    *p = 'f';
	    p++;
	    continue;
	case '\n':
	    *p = '\\';
	    p++;
	    *p = 'n';
	    p++;
	    continue;
	case '\r':
	    *p = '\\';
	    p++;
	    *p = 'r';
	    p++;
	    continue;
	case '\t':
	    *p = '\\';
	    p++;
	    *p = 't';
	    p++;
	    continue;
	case '\v':
	    *p = '\\';
	    p++;
	    *p = 'v';
	    p++;
	    continue;
	case '\0':
	    if (length == -1) {
		return p - dst;
	    }
	    /*
	     * If we reach this point, there's an embedded NULL in the
	     * string range being processed, which should not happen when
	     * the encoding rules for Tcl strings are properly followed.
	     * If the day ever comes when we stop tolerating such things,
	     * this is where to put the Tcl_Panic().
	     */
	    break;
	}
	*p = *src;
	p++;
    }
    return p - dst;
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_Merge --
 *
 *	Given a collection of strings, merge them together into a single
 *	string that has proper Tcl list structured (i.e. Tcl_SplitList may be
 *	used to retrieve strings equal to the original elements, and Tcl_Eval
 *	will parse the string back into its original elements).
 *
 * Results:
 *	The return value is the address of a dynamically-allocated string
 *	containing the merged list.
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

char *
Tcl_Merge(
    int argc,			/* How many strings to merge. */
    CONST char * CONST *argv)	/* Array of string values. */
{
#   define LOCAL_SIZE 20
    int localFlags[LOCAL_SIZE], *flagPtr = NULL;
    int i, bytesNeeded = 0;
    char *result, *dst;
    const int maxFlags = UINT_MAX / sizeof(int);

    if (argc == 0) {
	/*
	 * Handle empty list case first, so logic of the general case
	 * can be simpler.
	 */
	result = ckalloc(1);
	result[0] = '\0';
	return result;
    }

    /*
     * Pass 1: estimate space, gather flags.
     */

    if (argc <= LOCAL_SIZE) {
	flagPtr = localFlags;
    } else if (argc > maxFlags) {
	/*
	 * We cannot allocate a large enough flag array to format this
	 * list in one pass.  We could imagine converting this routine
	 * to a multi-pass implementation, but for sizeof(int) == 4,
	 * the limit is a max of 2^30 list elements and since each element
	 * is at least one byte formatted, and requires one byte space
	 * between it and the next one, that a minimum space requirement
	 * of 2^31 bytes, which is already INT_MAX. If we tried to format
	 * a list of > maxFlags elements, we're just going to overflow
	 * the size limits on the formatted string anyway, so just issue
	 * that same panic early.
	 */
	Tcl_Panic("max size for a Tcl value (%d bytes) exceeded", INT_MAX);
    } else {
	flagPtr = (int *) ckalloc((unsigned) argc*sizeof(int));
    }
    for (i = 0; i < argc; i++) {
	flagPtr[i] = ( i ? TCL_DONT_QUOTE_HASH : 0 );
	bytesNeeded += TclScanElement(argv[i], -1, &flagPtr[i]);
	if (bytesNeeded < 0) {
	    Tcl_Panic("max size for a Tcl value (%d bytes) exceeded", INT_MAX);
	}
    }
    if (bytesNeeded > INT_MAX - argc + 1) {
	Tcl_Panic("max size for a Tcl value (%d bytes) exceeded", INT_MAX);
    }
    bytesNeeded += argc;

    /*
     * Pass two: copy into the result area.
     */

    result = ckalloc((unsigned) bytesNeeded);
    dst = result;
    for (i = 0; i < argc; i++) {
	flagPtr[i] |= ( i ? TCL_DONT_QUOTE_HASH : 0 );
	dst += TclConvertElement(argv[i], -1, dst, flagPtr[i]);
	*dst = ' ';
	dst++;
    }
    dst[-1] = 0;

    if (flagPtr != localFlags) {
	ckfree((char *) flagPtr);
    }
    return result;
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_Backslash --
 *
 *	Figure out how to handle a backslash sequence.
 *
 * Results:
 *	The return value is the character that should be substituted in place
 *	of the backslash sequence that starts at src. If readPtr isn't NULL
 *	then it is filled in with a count of the number of characters in the
 *	backslash sequence.
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

char
Tcl_Backslash(
    CONST char *src,		/* Points to the backslash character of a
				 * backslash sequence. */
    int *readPtr)		/* Fill in with number of characters read from
				 * src, unless NULL. */
{
    char buf[TCL_UTF_MAX];
    Tcl_UniChar ch;

    Tcl_UtfBackslash(src, readPtr, buf);
    TclUtfToUniChar(buf, &ch);
    return (char) ch;
}

/*
 *----------------------------------------------------------------------
 *
 * TclTrimRight --
 *	Takes two counted strings in the Tcl encoding which must both be
 *	null terminated.  Conceptually trims from the right side of the
 *	first string all characters found in the second string.
 *
 * Results:
 *	The number of bytes to be removed from the end of the string.
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

int
TclTrimRight(
    const char *bytes,	/* String to be trimmed... */
    int numBytes,	/* ...and its length in bytes */
    const char *trim,	/* String of trim characters... */
    int numTrim)	/* ...and its length in bytes */
{
    const char *p = bytes + numBytes;
    int pInc;

    if ((bytes[numBytes] != '\0') || (trim[numTrim] != '\0')) {
	Tcl_Panic("TclTrimRight works only on null-terminated strings");
    }

    /* Empty strings -> nothing to do */
    if ((numBytes == 0) || (numTrim == 0)) {
	return 0;
    }

    /* Outer loop: iterate over string to be trimmed */
    do {
	Tcl_UniChar ch1;
	const char *q = trim;
	int bytesLeft = numTrim;

	p = Tcl_UtfPrev(p, bytes);
 	pInc = TclUtfToUniChar(p, &ch1);

	/* Inner loop: scan trim string for match to current character */
	do {
	    Tcl_UniChar ch2;
	    int qInc = TclUtfToUniChar(q, &ch2);

	    if (ch1 == ch2) {
		break;
	    }

	    q += qInc;
	    bytesLeft -= qInc;
	} while (bytesLeft);

	if (bytesLeft == 0) {
	    /* No match; trim task done; *p is last non-trimmed char */
	    p += pInc;
	    break;
	}
    } while (p > bytes);

    return numBytes - (p - bytes);
}

/*
 *----------------------------------------------------------------------
 *
 * TclTrimLeft --
 *	Takes two counted strings in the Tcl encoding which must both be
 *	null terminated.  Conceptually trims from the left side of the
 *	first string all characters found in the second string.
 *
 * Results:
 *	The number of bytes to be removed from the start of the string.
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

int
TclTrimLeft(
    const char *bytes,	/* String to be trimmed... */
    int numBytes,	/* ...and its length in bytes */
    const char *trim,	/* String of trim characters... */
    int numTrim)	/* ...and its length in bytes */
{
    const char *p = bytes;

    if ((bytes[numBytes] != '\0') || (trim[numTrim] != '\0')) {
	Tcl_Panic("TclTrimLeft works only on null-terminated strings");
    }

    /* Empty strings -> nothing to do */
    if ((numBytes == 0) || (numTrim == 0)) {
	return 0;
    }

    /* Outer loop: iterate over string to be trimmed */
    do {
	Tcl_UniChar ch1;
	int pInc = TclUtfToUniChar(p, &ch1);
	const char *q = trim;
	int bytesLeft = numTrim;

	/* Inner loop: scan trim string for match to current character */
	do {
	    Tcl_UniChar ch2;
	    int qInc = TclUtfToUniChar(q, &ch2);

	    if (ch1 == ch2) {
		break;
	    }

	    q += qInc;
	    bytesLeft -= qInc;
	} while (bytesLeft);

	if (bytesLeft == 0) {
	    /* No match; trim task done; *p is first non-trimmed char */
	    break;
	}

	p += pInc;
	numBytes -= pInc;
    } while (numBytes);

    return p - bytes;
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_Concat --
 *
 *	Concatenate a set of strings into a single large string.
 *
 * Results:
 *	The return value is dynamically-allocated string containing a
 *	concatenation of all the strings in argv, with spaces between the
 *	original argv elements.
 *
 * Side effects:
 *	Memory is allocated for the result; the caller is responsible for
 *	freeing the memory.
 *
 *----------------------------------------------------------------------
 */

/* The whitespace characters trimmed during [concat] operations */
#define CONCAT_WS " \f\v\r\t\n"
#define CONCAT_WS_SIZE (int) (sizeof(CONCAT_WS "") - 1)

char *
Tcl_Concat(
    int argc,			/* Number of strings to concatenate. */
    CONST char * CONST *argv)	/* Array of strings to concatenate. */
{
    int i, needSpace = 0, bytesNeeded = 0;
    char *result, *p;

    /* Dispose of the empty result corner case first to simplify later code */
    if (argc == 0) {
	result = (char *) ckalloc(1);
	result[0] = '\0';
	return result;
    }

    /* First allocate the result buffer at the size required */
    for (i = 0;  i < argc;  i++) {
	bytesNeeded += strlen(argv[i]);
	if (bytesNeeded < 0) {
	    Tcl_Panic("Tcl_Concat: max size of Tcl value exceeded");
	}
    }
    if (bytesNeeded + argc - 1 < 0) {
	/*
	 * Panic test could be tighter, but not going to bother for
	 * this legacy routine.
	 */
	Tcl_Panic("Tcl_Concat: max size of Tcl value exceeded");
    }
    /* All element bytes + (argc - 1) spaces + 1 terminating NULL */
    result = (char *) ckalloc((unsigned) (bytesNeeded + argc));

    for (p = result, i = 0;  i < argc;  i++) {
	int trim, elemLength;
	const char *element;

	element = argv[i];
	elemLength = strlen(argv[i]);

	/* Trim away the leading whitespace */
	trim = TclTrimLeft(element, elemLength, CONCAT_WS, CONCAT_WS_SIZE);
	element += trim;
	elemLength -= trim;

	/*
	 * Trim away the trailing whitespace.  Do not permit trimming
	 * to expose a final backslash character.
	 */

	trim = TclTrimRight(element, elemLength, CONCAT_WS, CONCAT_WS_SIZE);
	trim -= trim && (element[elemLength - trim - 1] == '\\');
	elemLength -= trim;

	/* If we're left with empty element after trimming, do nothing */
	if (elemLength == 0) {
	    continue;
	}

	/* Append to the result with space if needed */
	if (needSpace) {
	    *p++ = ' ';
	}
	memcpy(p, element, (size_t) elemLength);
	p += elemLength;
	needSpace = 1;
    }
    *p = '\0';
    return result;
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_ConcatObj --
 *
 *	Concatenate the strings from a set of objects into a single string
 *	object with spaces between the original strings.
 *
 * Results:
 *	The return value is a new string object containing a concatenation of
 *	the strings in objv. Its ref count is zero.
 *
 * Side effects:
 *	A new object is created.
 *
 *----------------------------------------------------------------------
 */

Tcl_Obj *
Tcl_ConcatObj(
    int objc,			/* Number of objects to concatenate. */
    Tcl_Obj *CONST objv[])	/* Array of objects to concatenate. */
{
    int i, elemLength, needSpace = 0, bytesNeeded = 0;
    const char *element;
    Tcl_Obj *objPtr, *resPtr;

    /*
     * Check first to see if all the items are of list type or empty. If so,
     * we will concat them together as lists, and return a list object. This
     * is only valid when the lists are in canonical form.
     */

    for (i = 0;  i < objc;  i++) {
	int length;

	objPtr = objv[i];
	if (TclListObjIsCanonical(objPtr)) {
	    continue;
	}
	Tcl_GetStringFromObj(objPtr, &length);
	if (length > 0) {
	    break;
	}
    }
    if (i == objc) {
	Tcl_Obj **listv;
	int listc;

	resPtr = NULL;
	for (i = 0;  i < objc;  i++) {
	    /*
	     * Tcl_ListObjAppendList could be used here, but this saves us a
	     * bit of type checking (since we've already done it). Use of
	     * INT_MAX tells us to always put the new stuff on the end. It
	     * will be set right in Tcl_ListObjReplace.
	     * Note that all objs at this point are either lists or have an
	     * empty string rep.
	     */

	    objPtr = objv[i];
	    if (objPtr->bytes && objPtr->length == 0) {
		continue;
	    }
	    TclListObjGetElements(NULL, objPtr, &listc, &listv);
	    if (listc) {
		if (resPtr) {
		    Tcl_ListObjReplace(NULL, resPtr, INT_MAX, 0, listc, listv);
		} else {
		    resPtr = TclListObjCopy(NULL, objPtr);
		}
	    }
	}
	if (!resPtr) {
	    resPtr = Tcl_NewObj();
	}
	return resPtr;
    }

    /*
     * Something cannot be determined to be safe, so build the concatenation
     * the slow way, using the string representations.
     */

    /* First try to pre-allocate the size required */
    for (i = 0;  i < objc;  i++) {
	element = TclGetStringFromObj(objv[i], &elemLength);
	bytesNeeded += elemLength;
	if (bytesNeeded < 0) {
	    break;
	}
    }
    /*
     * Does not matter if this fails, will simply try later to build up
     * the string with each Append reallocating as needed with the usual
     * string append algorithm.  When that fails it will report the error.
     */
    TclNewObj(resPtr);
    Tcl_AttemptSetObjLength(resPtr, bytesNeeded + objc - 1);
    Tcl_SetObjLength(resPtr, 0);

    for (i = 0;  i < objc;  i++) {
	int trim;

	element = TclGetStringFromObj(objv[i], &elemLength);

	/* Trim away the leading whitespace */
	trim = TclTrimLeft(element, elemLength, CONCAT_WS, CONCAT_WS_SIZE);
	element += trim;
	elemLength -= trim;

	/*
	 * Trim away the trailing whitespace.  Do not permit trimming
	 * to expose a final backslash character.
	 */

	trim = TclTrimRight(element, elemLength, CONCAT_WS, CONCAT_WS_SIZE);
	trim -= trim && (element[elemLength - trim - 1] == '\\');
	elemLength -= trim;

	/* If we're left with empty element after trimming, do nothing */
	if (elemLength == 0) {
	    continue;
	}

	/* Append to the result with space if needed */
	if (needSpace) {
	    Tcl_AppendToObj(resPtr, " ", 1);
	}
	Tcl_AppendToObj(resPtr, element, elemLength);
	needSpace = 1;
    }
    return resPtr;
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_StringMatch --
 *
 *	See if a particular string matches a particular pattern.
 *
 * Results:
 *	The return value is 1 if string matches pattern, and 0 otherwise. The
 *	matching operation permits the following special characters in the
 *	pattern: *?\[] (see the manual entry for details on what these mean).
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

int
Tcl_StringMatch(
    CONST char *str,		/* String. */
    CONST char *pattern)	/* Pattern, which may contain special
				 * characters. */
{
    return Tcl_StringCaseMatch(str, pattern, 0);
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_StringCaseMatch --
 *
 *	See if a particular string matches a particular pattern. Allows case
 *	insensitivity.
 *
 * Results:
 *	The return value is 1 if string matches pattern, and 0 otherwise. The
 *	matching operation permits the following special characters in the
 *	pattern: *?\[] (see the manual entry for details on what these mean).
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

int
Tcl_StringCaseMatch(
    CONST char *str,		/* String. */
    CONST char *pattern,	/* Pattern, which may contain special
				 * characters. */
    int nocase)			/* 0 for case sensitive, 1 for insensitive */
{
    int p, charLen;
    CONST char *pstart = pattern;
    Tcl_UniChar ch1, ch2;

    while (1) {
	p = *pattern;

	/*
	 * See if we're at the end of both the pattern and the string. If so,
	 * we succeeded. If we're at the end of the pattern but not at the end
	 * of the string, we failed.
	 */

	if (p == '\0') {
	    return (*str == '\0');
	}
	if ((*str == '\0') && (p != '*')) {
	    return 0;
	}

	/*
	 * Check for a "*" as the next pattern character. It matches any
	 * substring. We handle this by calling ourselves recursively for each
	 * postfix of string, until either we match or we reach the end of the
	 * string.
	 */

	if (p == '*') {
	    /*
	     * Skip all successive *'s in the pattern
	     */

	    while (*(++pattern) == '*') {}
	    p = *pattern;
	    if (p == '\0') {
		return 1;
	    }

	    /*
	     * This is a special case optimization for single-byte utf.
	     */

	    if (UCHAR(*pattern) < 0x80) {
		ch2 = (Tcl_UniChar)
			(nocase ? tolower(UCHAR(*pattern)) : UCHAR(*pattern));
	    } else {
		Tcl_UtfToUniChar(pattern, &ch2);
		if (nocase) {
		    ch2 = Tcl_UniCharToLower(ch2);
		}
	    }

	    while (1) {
		/*
		 * Optimization for matching - cruise through the string
		 * quickly if the next char in the pattern isn't a special
		 * character
		 */

		if ((p != '[') && (p != '?') && (p != '\\')) {
		    if (nocase) {
			while (*str) {
			    charLen = TclUtfToUniChar(str, &ch1);
			    if (ch2==ch1 || ch2==Tcl_UniCharToLower(ch1)) {
				break;
			    }
			    str += charLen;
			}
		    } else {
			/*
			 * There's no point in trying to make this code
			 * shorter, as the number of bytes you want to compare
			 * each time is non-constant.
			 */

			while (*str) {
			    charLen = TclUtfToUniChar(str, &ch1);
			    if (ch2 == ch1) {
				break;
			    }
			    str += charLen;
			}
		    }
		}
		if (Tcl_StringCaseMatch(str, pattern, nocase)) {
		    return 1;
		}
		if (*str == '\0') {
		    return 0;
		}
		str += TclUtfToUniChar(str, &ch1);
	    }
	}

	/*
	 * Check for a "?" as the next pattern character. It matches any
	 * single character.
	 */

	if (p == '?') {
	    pattern++;
	    str += TclUtfToUniChar(str, &ch1);
	    continue;
	}

	/*
	 * Check for a "[" as the next pattern character. It is followed by a
	 * list of characters that are acceptable, or by a range (two
	 * characters separated by "-").
	 */

	if (p == '[') {
	    Tcl_UniChar startChar, endChar;

	    pattern++;
	    if (UCHAR(*str) < 0x80) {
		ch1 = (Tcl_UniChar)
			(nocase ? tolower(UCHAR(*str)) : UCHAR(*str));
		str++;
	    } else {
		str += Tcl_UtfToUniChar(str, &ch1);
		if (nocase) {
		    ch1 = Tcl_UniCharToLower(ch1);
		}
	    }
	    while (1) {
		if ((*pattern == ']') || (*pattern == '\0')) {
		    return 0;
		}
		if (UCHAR(*pattern) < 0x80) {
		    startChar = (Tcl_UniChar) (nocase
			    ? tolower(UCHAR(*pattern)) : UCHAR(*pattern));
		    pattern++;
		} else {
		    pattern += Tcl_UtfToUniChar(pattern, &startChar);
		    if (nocase) {
			startChar = Tcl_UniCharToLower(startChar);
		    }
		}
		if (*pattern == '-') {
		    pattern++;
		    if (*pattern == '\0') {
			return 0;
		    }
		    if (UCHAR(*pattern) < 0x80) {
			endChar = (Tcl_UniChar) (nocase
				? tolower(UCHAR(*pattern)) : UCHAR(*pattern));
			pattern++;
		    } else {
			pattern += Tcl_UtfToUniChar(pattern, &endChar);
			if (nocase) {
			    endChar = Tcl_UniCharToLower(endChar);
			}
		    }
		    if (((startChar <= ch1) && (ch1 <= endChar))
			    || ((endChar <= ch1) && (ch1 <= startChar))) {
			/*
			 * Matches ranges of form [a-z] or [z-a].
			 */

			break;
		    }
		} else if (startChar == ch1) {
		    break;
		}
	    }
	    while (*pattern != ']') {
		if (*pattern == '\0') {
		    pattern = Tcl_UtfPrev(pattern, pstart);
		    break;
		}
		pattern++;
	    }
	    pattern++;
	    continue;
	}

	/*
	 * If the next pattern character is '\', just strip off the '\' so we
	 * do exact matching on the character that follows.
	 */

	if (p == '\\') {
	    pattern++;
	    if (*pattern == '\0') {
		return 0;
	    }
	}

	/*
	 * There's no special character. Just make sure that the next bytes of
	 * each string match.
	 */

	str += TclUtfToUniChar(str, &ch1);
	pattern += TclUtfToUniChar(pattern, &ch2);
	if (nocase) {
	    if (Tcl_UniCharToLower(ch1) != Tcl_UniCharToLower(ch2)) {
		return 0;
	    }
	} else if (ch1 != ch2) {
	    return 0;
	}
    }
}

/*
 *----------------------------------------------------------------------
 *
 * TclByteArrayMatch --
 *
 *	See if a particular string matches a particular pattern.  Does not
 *	allow for case insensitivity.
 *	Parallels tclUtf.c:TclUniCharMatch, adjusted for char* and sans nocase.
 *
 * Results:
 *	The return value is 1 if string matches pattern, and 0 otherwise. The
 *	matching operation permits the following special characters in the
 *	pattern: *?\[] (see the manual entry for details on what these mean).
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

int
TclByteArrayMatch(
    const unsigned char *string,	/* String. */
    int strLen,				/* Length of String */
    const unsigned char *pattern,	/* Pattern, which may contain special
					 * characters. */
    int ptnLen,				/* Length of Pattern */
    int flags)
{
    const unsigned char *stringEnd, *patternEnd;
    unsigned char p;

    stringEnd = string + strLen;
    patternEnd = pattern + ptnLen;

    while (1) {
	/*
	 * See if we're at the end of both the pattern and the string. If so,
	 * we succeeded. If we're at the end of the pattern but not at the end
	 * of the string, we failed.
	 */

	if (pattern == patternEnd) {
	    return (string == stringEnd);
	}
	p = *pattern;
	if ((string == stringEnd) && (p != '*')) {
	    return 0;
	}

	/*
	 * Check for a "*" as the next pattern character. It matches any
	 * substring. We handle this by skipping all the characters up to the
	 * next matching one in the pattern, and then calling ourselves
	 * recursively for each postfix of string, until either we match or we
	 * reach the end of the string.
	 */

	if (p == '*') {
	    /*
	     * Skip all successive *'s in the pattern.
	     */

	    while ((++pattern < patternEnd) && (*pattern == '*')) {
		/* empty body */
	    }
	    if (pattern == patternEnd) {
		return 1;
	    }
	    p = *pattern;
	    while (1) {
		/*
		 * Optimization for matching - cruise through the string
		 * quickly if the next char in the pattern isn't a special
		 * character.
		 */

		if ((p != '[') && (p != '?') && (p != '\\')) {
		    while ((string < stringEnd) && (p != *string)) {
			string++;
		    }
		}
		if (TclByteArrayMatch(string, stringEnd - string,
				pattern, patternEnd - pattern, 0)) {
		    return 1;
		}
		if (string == stringEnd) {
		    return 0;
		}
		string++;
	    }
	}

	/*
	 * Check for a "?" as the next pattern character. It matches any
	 * single character.
	 */

	if (p == '?') {
	    pattern++;
	    string++;
	    continue;
	}

	/*
	 * Check for a "[" as the next pattern character. It is followed by a
	 * list of characters that are acceptable, or by a range (two
	 * characters separated by "-").
	 */

	if (p == '[') {
	    unsigned char ch1, startChar, endChar;

	    pattern++;
	    ch1 = *string;
	    string++;
	    while (1) {
		if ((*pattern == ']') || (pattern == patternEnd)) {
		    return 0;
		}
		startChar = *pattern;
		pattern++;
		if (*pattern == '-') {
		    pattern++;
		    if (pattern == patternEnd) {
			return 0;
		    }
		    endChar = *pattern;
		    pattern++;
		    if (((startChar <= ch1) && (ch1 <= endChar))
			    || ((endChar <= ch1) && (ch1 <= startChar))) {
			/*
			 * Matches ranges of form [a-z] or [z-a].
			 */
			break;
		    }
		} else if (startChar == ch1) {
		    break;
		}
	    }
	    while (*pattern != ']') {
		if (pattern == patternEnd) {
		    pattern--;
		    break;
		}
		pattern++;
	    }
	    pattern++;
	    continue;
	}

	/*
	 * If the next pattern character is '\', just strip off the '\' so we
	 * do exact matching on the character that follows.
	 */

	if (p == '\\') {
	    if (++pattern == patternEnd) {
		return 0;
	    }
	}

	/*
	 * There's no special character. Just make sure that the next bytes of
	 * each string match.
	 */

	if (*string != *pattern) {
	    return 0;
	}
	string++;
	pattern++;
    }
}

/*
 *----------------------------------------------------------------------
 *
 * TclStringMatchObj --
 *
 *	See if a particular string matches a particular pattern.
 *	Allows case insensitivity.  This is the generic multi-type handler
 *	for the various matching algorithms.
 *
 * Results:
 *	The return value is 1 if string matches pattern, and 0 otherwise. The
 *	matching operation permits the following special characters in the
 *	pattern: *?\[] (see the manual entry for details on what these mean).
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

int
TclStringMatchObj(
    Tcl_Obj *strObj,	/* string object. */
    Tcl_Obj *ptnObj,	/* pattern object. */
    int flags)		/* Only TCL_MATCH_NOCASE should be passed or 0. */
{
    int match, length, plen;

    /*
     * Promote based on the type of incoming object.
     * XXX: Currently doesn't take advantage of exact-ness that
     * XXX: TclReToGlob tells us about
    trivial = nocase ? 0 : TclMatchIsTrivial(TclGetString(ptnObj));
     */

    if (strObj->typePtr == &tclStringType) {
	Tcl_UniChar *udata, *uptn;

	udata = Tcl_GetUnicodeFromObj(strObj, &length);
	uptn  = Tcl_GetUnicodeFromObj(ptnObj, &plen);
	match = TclUniCharMatch(udata, length, uptn, plen, flags);
    } else if (TclIsPureByteArray(strObj) && !flags) {
	unsigned char *data, *ptn;

	data = Tcl_GetByteArrayFromObj(strObj, &length);
	ptn  = Tcl_GetByteArrayFromObj(ptnObj, &plen);
	match = TclByteArrayMatch(data, length, ptn, plen, 0);
    } else {
	match = Tcl_StringCaseMatch(TclGetString(strObj),
		TclGetString(ptnObj), flags);
    }
    return match;
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_DStringInit --
 *
 *	Initializes a dynamic string, discarding any previous contents of the
 *	string (Tcl_DStringFree should have been called already if the dynamic
 *	string was previously in use).
 *
 * Results:
 *	None.
 *
 * Side effects:
 *	The dynamic string is initialized to be empty.
 *
 *----------------------------------------------------------------------
 */

void
Tcl_DStringInit(
    Tcl_DString *dsPtr)		/* Pointer to structure for dynamic string. */
{
    dsPtr->string = dsPtr->staticSpace;
    dsPtr->length = 0;
    dsPtr->spaceAvl = TCL_DSTRING_STATIC_SIZE;
    dsPtr->staticSpace[0] = '\0';
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_DStringAppend --
 *
 *	Append more bytes to the current value of a dynamic string.
 *
 * Results:
 *	The return value is a pointer to the dynamic string's new value.
 *
 * Side effects:
 *	Length bytes from "bytes" (or all of "bytes" if length is less than
 *	zero) are added to the current value of the string. Memory gets
 *	reallocated if needed to accomodate the string's new size.
 *
 *----------------------------------------------------------------------
 */

char *
Tcl_DStringAppend(
    Tcl_DString *dsPtr,		/* Structure describing dynamic string. */
    CONST char *bytes,		/* String to append. If length is -1 then this
				 * must be null-terminated. */
    int length)			/* Number of bytes from "bytes" to append. If
				 * < 0, then append all of bytes, up to null
				 * at end. */
{
    int newSize;
    char *dst;
    CONST char *end;

    if (length < 0) {
	length = strlen(bytes);
    }
    newSize = length + dsPtr->length;

    /*
     * Allocate a larger buffer for the string if the current one isn't large
     * enough. Allocate extra space in the new buffer so that there will be
     * room to grow before we have to allocate again.
     */

    if (newSize >= dsPtr->spaceAvl) {
	dsPtr->spaceAvl = newSize * 2;
	if (dsPtr->string == dsPtr->staticSpace) {
	    char *newString = ckalloc((unsigned) dsPtr->spaceAvl);

	    memcpy(newString, dsPtr->string, (size_t) dsPtr->length);
	    dsPtr->string = newString;
	} else {
	    dsPtr->string = ckrealloc((void *) dsPtr->string,
		    (size_t) dsPtr->spaceAvl);
	}
    }

    /*
     * Copy the new string into the buffer at the end of the old one.
     */

    for (dst = dsPtr->string + dsPtr->length, end = bytes+length;
	    bytes < end; bytes++, dst++) {
	*dst = *bytes;
    }
    *dst = '\0';
    dsPtr->length += length;
    return dsPtr->string;
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_DStringAppendElement --
 *
 *	Append a list element to the current value of a dynamic string.
 *
 * Results:
 *	The return value is a pointer to the dynamic string's new value.
 *
 * Side effects:
 *	String is reformatted as a list element and added to the current value
 *	of the string. Memory gets reallocated if needed to accomodate the
 *	string's new size.
 *
 *----------------------------------------------------------------------
 */

char *
Tcl_DStringAppendElement(
    Tcl_DString *dsPtr,		/* Structure describing dynamic string. */
    CONST char *element)	/* String to append. Must be
				 * null-terminated. */
{
    char *dst = dsPtr->string + dsPtr->length;
    int needSpace = TclNeedSpace(dsPtr->string, dst);
    int flags = needSpace ? TCL_DONT_QUOTE_HASH : 0;
    int newSize = dsPtr->length + needSpace
	    + TclScanElement(element, -1, &flags);

    /*
     * Allocate a larger buffer for the string if the current one isn't large
     * enough. Allocate extra space in the new buffer so that there will be
     * room to grow before we have to allocate again. SPECIAL NOTE: must use
     * memcpy, not strcpy, to copy the string to a larger buffer, since there
     * may be embedded NULLs in the string in some cases.
     */

    if (newSize >= dsPtr->spaceAvl) {
	dsPtr->spaceAvl = newSize * 2;
	if (dsPtr->string == dsPtr->staticSpace) {
	    char *newString = ckalloc((unsigned) dsPtr->spaceAvl);

	    memcpy(newString, dsPtr->string, (size_t) dsPtr->length);
	    dsPtr->string = newString;
	} else {
	    dsPtr->string = (char *) ckrealloc((void *) dsPtr->string,
		    (size_t) dsPtr->spaceAvl);
	}
	dst = dsPtr->string + dsPtr->length;
    }

    /*
     * Convert the new string to a list element and copy it into the buffer at
     * the end, with a space, if needed.
     */

    if (needSpace) {
	*dst = ' ';
	dst++;
	dsPtr->length++;

	/*
	 * If we need a space to separate this element from preceding stuff,
	 * then this element will not lead a list, and need not have it's
	 * leading '#' quoted.
	 */

	flags |= TCL_DONT_QUOTE_HASH;
    }
    dsPtr->length += TclConvertElement(element, -1, dst, flags);
    dsPtr->string[dsPtr->length] = '\0';
    return dsPtr->string;
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_DStringSetLength --
 *
 *	Change the length of a dynamic string. This can cause the string to
 *	either grow or shrink, depending on the value of length.
 *
 * Results:
 *	None.
 *
 * Side effects:
 *	The length of dsPtr is changed to length and a null byte is stored at
 *	that position in the string. If length is larger than the space
 *	allocated for dsPtr, then a panic occurs.
 *
 *----------------------------------------------------------------------
 */

void
Tcl_DStringSetLength(
    Tcl_DString *dsPtr,		/* Structure describing dynamic string. */
    int length)			/* New length for dynamic string. */
{
    int newsize;

    if (length < 0) {
	length = 0;
    }
    if (length >= dsPtr->spaceAvl) {
	/*
	 * There are two interesting cases here. In the first case, the user
	 * may be trying to allocate a large buffer of a specific size. It
	 * would be wasteful to overallocate that buffer, so we just allocate
	 * enough for the requested size plus the trailing null byte. In the
	 * second case, we are growing the buffer incrementally, so we need
	 * behavior similar to Tcl_DStringAppend. The requested length will
	 * usually be a small delta above the current spaceAvl, so we'll end
	 * up doubling the old size. This won't grow the buffer quite as
	 * quickly, but it should be close enough.
	 */

	newsize = dsPtr->spaceAvl * 2;
	if (length < newsize) {
	    dsPtr->spaceAvl = newsize;
	} else {
	    dsPtr->spaceAvl = length + 1;
	}
	if (dsPtr->string == dsPtr->staticSpace) {
	    char *newString = ckalloc((unsigned) dsPtr->spaceAvl);

	    memcpy(newString, dsPtr->string, (size_t) dsPtr->length);
	    dsPtr->string = newString;
	} else {
	    dsPtr->string = (char *) ckrealloc((void *) dsPtr->string,
		    (size_t) dsPtr->spaceAvl);
	}
    }
    dsPtr->length = length;
    dsPtr->string[length] = 0;
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_DStringFree --
 *
 *	Frees up any memory allocated for the dynamic string and reinitializes
 *	the string to an empty state.
 *
 * Results:
 *	None.
 *
 * Side effects:
 *	The previous contents of the dynamic string are lost, and the new
 *	value is an empty string.
 *
 *----------------------------------------------------------------------
 */

void
Tcl_DStringFree(
    Tcl_DString *dsPtr)		/* Structure describing dynamic string. */
{
    if (dsPtr->string != dsPtr->staticSpace) {
	ckfree(dsPtr->string);
    }
    dsPtr->string = dsPtr->staticSpace;
    dsPtr->length = 0;
    dsPtr->spaceAvl = TCL_DSTRING_STATIC_SIZE;
    dsPtr->staticSpace[0] = '\0';
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_DStringResult --
 *
 *	This function moves the value of a dynamic string into an interpreter
 *	as its string result. Afterwards, the dynamic string is reset to an
 *	empty string.
 *
 * Results:
 *	None.
 *
 * Side effects:
 *	The string is "moved" to interp's result, and any existing string
 *	result for interp is freed. dsPtr is reinitialized to an empty string.
 *
 *----------------------------------------------------------------------
 */

void
Tcl_DStringResult(
    Tcl_Interp *interp,		/* Interpreter whose result is to be reset. */
    Tcl_DString *dsPtr)		/* Dynamic string that is to become the
				 * result of interp. */
{
    Tcl_ResetResult(interp);

    if (dsPtr->string != dsPtr->staticSpace) {
	interp->result = dsPtr->string;
	interp->freeProc = TCL_DYNAMIC;
    } else if (dsPtr->length < TCL_RESULT_SIZE) {
	interp->result = ((Interp *) interp)->resultSpace;
	strcpy(interp->result, dsPtr->string);
    } else {
	Tcl_SetResult(interp, dsPtr->string, TCL_VOLATILE);
    }

    dsPtr->string = dsPtr->staticSpace;
    dsPtr->length = 0;
    dsPtr->spaceAvl = TCL_DSTRING_STATIC_SIZE;
    dsPtr->staticSpace[0] = '\0';
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_DStringGetResult --
 *
 *	This function moves an interpreter's result into a dynamic string.
 *
 * Results:
 *	None.
 *
 * Side effects:
 *	The interpreter's string result is cleared, and the previous contents
 *	of dsPtr are freed.
 *
 *	If the string result is empty, the object result is moved to the
 *	string result, then the object result is reset.
 *
 *----------------------------------------------------------------------
 */

void
Tcl_DStringGetResult(
    Tcl_Interp *interp,		/* Interpreter whose result is to be reset. */
    Tcl_DString *dsPtr)		/* Dynamic string that is to become the result
				 * of interp. */
{
    Interp *iPtr = (Interp *) interp;

    if (dsPtr->string != dsPtr->staticSpace) {
	ckfree(dsPtr->string);
    }

    /*
     * If the string result is empty, move the object result to the string
     * result, then reset the object result.
     */

    (void) Tcl_GetStringResult(interp);

    dsPtr->length = strlen(iPtr->result);
    if (iPtr->freeProc != NULL) {
	if (iPtr->freeProc == TCL_DYNAMIC) {
	    dsPtr->string = iPtr->result;
	    dsPtr->spaceAvl = dsPtr->length+1;
	} else {
	    dsPtr->string = (char *) ckalloc((unsigned) (dsPtr->length+1));
	    memcpy(dsPtr->string, iPtr->result, (unsigned) dsPtr->length+1);
	    (*iPtr->freeProc)(iPtr->result);
	}
	dsPtr->spaceAvl = dsPtr->length+1;
	iPtr->freeProc = NULL;
    } else {
	if (dsPtr->length < TCL_DSTRING_STATIC_SIZE) {
	    dsPtr->string = dsPtr->staticSpace;
	    dsPtr->spaceAvl = TCL_DSTRING_STATIC_SIZE;
	} else {
	    dsPtr->string = (char *) ckalloc((unsigned) (dsPtr->length + 1));
	    dsPtr->spaceAvl = dsPtr->length + 1;
	}
	memcpy(dsPtr->string, iPtr->result, (unsigned) dsPtr->length+1);
    }

    iPtr->result = iPtr->resultSpace;
    iPtr->resultSpace[0] = 0;
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_DStringStartSublist --
 *
 *	This function adds the necessary information to a dynamic string
 *	(e.g. " {") to start a sublist. Future element appends will be in the
 *	sublist rather than the main list.
 *
 * Results:
 *	None.
 *
 * Side effects:
 *	Characters get added to the dynamic string.
 *
 *----------------------------------------------------------------------
 */

void
Tcl_DStringStartSublist(
    Tcl_DString *dsPtr)		/* Dynamic string. */
{
    if (TclNeedSpace(dsPtr->string, dsPtr->string + dsPtr->length)) {
	Tcl_DStringAppend(dsPtr, " {", -1);
    } else {
	Tcl_DStringAppend(dsPtr, "{", -1);
    }
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_DStringEndSublist --
 *
 *	This function adds the necessary characters to a dynamic string to end
 *	a sublist (e.g. "}"). Future element appends will be in the enclosing
 *	(sub)list rather than the current sublist.
 *
 * Results:
 *	None.
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

void
Tcl_DStringEndSublist(
    Tcl_DString *dsPtr)		/* Dynamic string. */
{
    Tcl_DStringAppend(dsPtr, "}", -1);
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_PrintDouble --
 *
 *	Given a floating-point value, this function converts it to an ASCII
 *	string using.
 *
 * Results:
 *	The ASCII equivalent of "value" is written at "dst". It is written
 *	using the current precision, and it is guaranteed to contain a decimal
 *	point or exponent, so that it looks like a floating-point value and
 *	not an integer.
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

void
Tcl_PrintDouble(
    Tcl_Interp *interp,		/* Interpreter whose tcl_precision variable
				 * used to be used to control printing. It's
				 * ignored now. */
    double value,		/* Value to print as string. */
    char *dst)			/* Where to store converted value; must have
				 * at least TCL_DOUBLE_SPACE characters. */
{
    char *p, c;
    int exponent;
    int signum;
    char* digits;
    char* end;

    int *precisionPtr = Tcl_GetThreadData(&precisionKey, (int)sizeof(int));

    /*
	 * Handle NaN.
	 */

	if (TclIsNaN(value)) {
	    TclFormatNaN(value, dst);
	    return;
	}

	/*
	 * Handle infinities.
	 */

	if (TclIsInfinite(value)) {
	/*
	 * Remember to copy the terminating NUL too.
	 */

	    if (value < 0) {
	    memcpy(dst, "-Inf", 5);
	    } else {
	    memcpy(dst, "Inf", 4);
	    }
	    return;
	}

	/*
	 * Ordinary (normal and denormal) values.
	 */

    if (*precisionPtr == 0) {
	digits = TclDoubleDigits(value, -1, TCL_DD_SHORTEST,
				 &exponent, &signum, &end);
    } else {
	/*
	 * There are at least two possible interpretations for tcl_precision.
	 *
	 * The first is, "choose the decimal representation having
	 * $tcl_precision digits of significance that is nearest to the
	 * given number, breaking ties by rounding to even, and then
	 * trimming trailing zeros." This gives the greatest possible
	 * precision in the decimal string, but offers the anomaly that
	 * [expr 0.1] will be "0.10000000000000001".
	 *
	 * The second is "choose the decimal representation having at
	 * most $tcl_precision digits of significance that is nearest
	 * to the given number. If no such representation converts
	 * exactly to the given number, choose the one that is closest,
	 * breaking ties by rounding to even. If more than one such
	 * representation converts exactly to the given number, choose
	 * the shortest, breaking ties in favour of the nearest, breaking
	 * remaining ties in favour of the one ending in an even digit."
	 *
	 * Tcl 8.4 implements the first of these, which gives rise to
	 * anomalies in formatting:
	 *
	 * % expr 0.1
	 * 0.10000000000000001
	 * % expr 0.01
	 * 0.01
	 * % expr 1e-7
	 * 9.9999999999999995e-08
	 *
	 * For human readability, it appears better to choose the second rule,
	 * and let [expr 0.1] return 0.1. But for 8.4 compatibility, we
	 * prefer the first (the recommended zero value for tcl_precision
	 * avoids the problem entirely).
	 *
	 * Uncomment TCL_DD_SHORTEN_FLAG in the next call to prefer the
	 * method that allows floating point values to be shortened if
	 * it can be done without loss of precision.
	 */

	digits = TclDoubleDigits(value, *precisionPtr,
				 TCL_DD_E_FORMAT /* | TCL_DD_SHORTEN_FLAG */,
				 &exponent, &signum, &end);
    }
	if (signum) {
	    *dst++ = '-';
	}
    p = digits;
    if (exponent < -4 || exponent > 16) {
	/*
	 * E format for numbers < 1e-3 or >= 1e17.
	 */

	*dst++ = *p++;
	c = *p;
	if (c != '\0') {
	    *dst++ = '.';
	    while (c != '\0') {
		*dst++ = c;
		c = *++p;
	    }
	}
	/*
	 * Tcl 8.4 appears to format with at least a two-digit exponent; \
	 * preserve that behaviour when tcl_precision != 0
	 */
	if (*precisionPtr == 0) {
	    sprintf(dst, "e%+d", exponent);
	} else {
	    sprintf(dst, "e%+03d", exponent);
	}
    } else {
	/*
	 * F format for others.
	 */

	if (exponent < 0) {
	    *dst++ = '0';
	}
	c = *p;
	while (exponent-- >= 0) {
	    if (c != '\0') {
		*dst++ = c;
		c = *++p;
	    } else {
		*dst++ = '0';
	    }
	}
	*dst++ = '.';
	if (c == '\0') {
	    *dst++ = '0';
	} else {
	    while (++exponent < -1) {
		*dst++ = '0';
	    }
	    while (c != '\0') {
		*dst++ = c;
		c = *++p;
	    }
	}
	*dst++ = '\0';
    }
    ckfree(digits);
}

/*
 *----------------------------------------------------------------------
 *
 * TclPrecTraceProc --
 *
 *	This function is invoked whenever the variable "tcl_precision" is
 *	written.
 *
 * Results:
 *	Returns NULL if all went well, or an error message if the new value
 *	for the variable doesn't make sense.
 *
 * Side effects:
 *	If the new value doesn't make sense then this function undoes the
 *	effect of the variable modification. Otherwise it modifies the format
 *	string that's used by Tcl_PrintDouble.
 *
 *----------------------------------------------------------------------
 */

	/* ARGSUSED */
char *
TclPrecTraceProc(
    ClientData clientData,	/* Not used. */
    Tcl_Interp *interp,		/* Interpreter containing variable. */
    CONST char *name1,		/* Name of variable. */
    CONST char *name2,		/* Second part of variable name. */
    int flags)			/* Information about what happened. */
{
    Tcl_Obj* value;
    int prec;
    int *precisionPtr = Tcl_GetThreadData(&precisionKey, (int) sizeof(int));

    /*
     * If the variable is unset, then recreate the trace.
     */

    if (flags & TCL_TRACE_UNSETS) {
	if ((flags & TCL_TRACE_DESTROYED) && !Tcl_InterpDeleted(interp)) {
	    Tcl_TraceVar2(interp, name1, name2,
		    TCL_GLOBAL_ONLY|TCL_TRACE_READS|TCL_TRACE_WRITES
		    |TCL_TRACE_UNSETS, TclPrecTraceProc, clientData);
	}
	return NULL;
    }

    /*
     * When the variable is read, reset its value from our shared value. This
     * is needed in case the variable was modified in some other interpreter
     * so that this interpreter's value is out of date.
     */


    if (flags & TCL_TRACE_READS) {
	Tcl_SetVar2Ex(interp, name1, name2, Tcl_NewIntObj(*precisionPtr),
		flags & TCL_GLOBAL_ONLY);
	return NULL;
    }

    /*
     * The variable is being written. Check the new value and disallow it if
     * it isn't reasonable or if this is a safe interpreter (we don't want
     * safe interpreters messing up the precision of other interpreters).
     */

    if (Tcl_IsSafe(interp)) {
	return "can't modify precision from a safe interpreter";
    }
    value = Tcl_GetVar2Ex(interp, name1, name2, flags & TCL_GLOBAL_ONLY);
    if (value == NULL
	    || Tcl_GetIntFromObj((Tcl_Interp*) NULL, value, &prec) != TCL_OK
	    || prec < 0 || prec > TCL_MAX_PREC) {
	return "improper value for precision";
    }
    *precisionPtr = prec;
    return NULL;
}

/*
 *----------------------------------------------------------------------
 *
 * TclNeedSpace --
 *
 *	This function checks to see whether it is appropriate to add a space
 *	before appending a new list element to an existing string.
 *
 * Results:
 *	The return value is 1 if a space is appropriate, 0 otherwise.
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

int
TclNeedSpace(
    CONST char *start,		/* First character in string. */
    CONST char *end)		/* End of string (place where space will be
				 * added, if appropriate). */
{
    /*
     * A space is needed unless either:
     * (a) we're at the start of the string, or
     */

    if (end == start) {
	return 0;
    }

    /*
     * (b) we're at the start of a nested list-element, quoted with an open
     *	   curly brace; we can be nested arbitrarily deep, so long as the
     *	   first curly brace starts an element, so backtrack over open curly
     *	   braces that are trailing characters of the string; and
     */

    end = Tcl_UtfPrev(end, start);
    while (*end == '{') {
	if (end == start) {
	    return 0;
	}
	end = Tcl_UtfPrev(end, start);
    }

    /*
     * (c) the trailing character of the string is already a list-element
     *	   separator (according to TclFindElement); that is, one of these
     *	   characters:
     *		\u0009	\t	TAB
     *		\u000A	\n	NEWLINE
     *		\u000B	\v	VERTICAL TAB
     *		\u000C	\f	FORM FEED
     *		\u000D	\r	CARRIAGE RETURN
     *		\u0020		SPACE
     *	   with the condition that the penultimate character is not a
     *	   backslash.
     */

    if (*end > 0x20) {
	/*
	 * Performance tweak. All ASCII spaces are <= 0x20. So get a quick
	 * answer for most characters before comparing against all spaces in
	 * the switch below.
	 *
	 * NOTE: Remove this if other Unicode spaces ever get accepted as
	 * list-element separators.
	 */
	return 1;
    }
    switch (*end) {
    case ' ':
    case '\t':
    case '\n':
    case '\r':
    case '\v':
    case '\f':
	if ((end == start) || (end[-1] != '\\')) {
	    return 0;
	}
    }
    return 1;
}

/*
 *----------------------------------------------------------------------
 *
 * TclFormatInt --
 *
 *	This procedure formats an integer into a sequence of decimal digit
 *	characters in a buffer. If the integer is negative, a minus sign is
 *	inserted at the start of the buffer. A null character is inserted at
 *	the end of the formatted characters. It is the caller's
 *	responsibility to ensure that enough storage is available. This
 *	procedure has the effect of sprintf(buffer, "%ld", n) but is faster
 *	as proven in benchmarks.  This is key to UpdateStringOfInt, which
 *	is a common path for a lot of code (e.g. int-indexed arrays).
 *
 * Results:
 *	An integer representing the number of characters formatted, not
 *	including the terminating \0.
 *
 * Side effects:
 *	The formatted characters are written into the storage pointer to
 *	by the "buffer" argument.
 *
 *----------------------------------------------------------------------
 */

int
TclFormatInt(buffer, n)
    char *buffer;		/* Points to the storage into which the
				 * formatted characters are written. */
    long n;			/* The integer to format. */
{
    long intVal;
    int i;
    int numFormatted, j;
    char *digits = "0123456789";

    /*
     * Check first whether "n" is zero.
     */

    if (n == 0) {
	buffer[0] = '0';
	buffer[1] = 0;
	return 1;
    }

    /*
     * Check whether "n" is the maximum negative value. This is
     * -2^(m-1) for an m-bit word, and has no positive equivalent;
     * negating it produces the same value.
     */

    intVal = -n;			/* [Bug 3390638] Workaround for*/
    if (n == -n || intVal == n) {	/* broken compiler optimizers. */
	return sprintf(buffer, "%ld", n);
    }

    /*
     * Generate the characters of the result backwards in the buffer.
     */

    intVal = (n < 0? -n : n);
    i = 0;
    buffer[0] = '\0';
    do {
	i++;
	buffer[i] = digits[intVal % 10];
	intVal = intVal/10;
    } while (intVal > 0);
    if (n < 0) {
	i++;
	buffer[i] = '-';
    }
    numFormatted = i;

    /*
     * Now reverse the characters.
     */

    for (j = 0;  j < i;  j++, i--) {
	char tmp = buffer[i];
	buffer[i] = buffer[j];
	buffer[j] = tmp;
    }
    return numFormatted;
}

/*
 *----------------------------------------------------------------------
 *
 * TclGetIntForIndex --
 *
 *	This function returns an integer corresponding to the list index held
 *	in a Tcl object. The Tcl object's value is expected to be in the
 *	format integer([+-]integer)? or the format end([+-]integer)?.
 *
 * Results:
 *	The return value is normally TCL_OK, which means that the index was
 *	successfully stored into the location referenced by "indexPtr". If the
 *	Tcl object referenced by "objPtr" has the value "end", the value
 *	stored is "endValue". If "objPtr"s values is not of one of the
 *	expected formats, TCL_ERROR is returned and, if "interp" is non-NULL,
 *	an error message is left in the interpreter's result object.
 *
 * Side effects:
 *	The object referenced by "objPtr" might be converted to an integer,
 *	wide integer, or end-based-index object.
 *
 *----------------------------------------------------------------------
 */

int
TclGetIntForIndex(
    Tcl_Interp *interp,		/* Interpreter to use for error reporting. If
				 * NULL, then no error message is left after
				 * errors. */
    Tcl_Obj *objPtr,		/* Points to an object containing either "end"
				 * or an integer. */
    int endValue,		/* The value to be stored at "indexPtr" if
				 * "objPtr" holds "end". */
    int *indexPtr)		/* Location filled in with an integer
				 * representing an index. */
{
    int length;
    char *opPtr, *bytes;

    if (TclGetIntFromObj(NULL, objPtr, indexPtr) == TCL_OK) {
	return TCL_OK;
    }

    if (SetEndOffsetFromAny(NULL, objPtr) == TCL_OK) {
	/*
	 * If the object is already an offset from the end of the list, or can
	 * be converted to one, use it.
	 */

	*indexPtr = endValue + objPtr->internalRep.longValue;
	return TCL_OK;
    }

    bytes = TclGetStringFromObj(objPtr, &length);

    /*
     * Leading whitespace is acceptable in an index.
     */

    while (length && TclIsSpaceProc(*bytes)) {
	bytes++;
	length--;
    }

    if (TclParseNumber(NULL, NULL, NULL, bytes, length, (const char **)&opPtr,
	    TCL_PARSE_INTEGER_ONLY | TCL_PARSE_NO_WHITESPACE) == TCL_OK) {
	int code, first, second;
	char savedOp = *opPtr;

	if ((savedOp != '+') && (savedOp != '-')) {
	    goto parseError;
	}
	if (TclIsSpaceProc(opPtr[1])) {
	    goto parseError;
	}
	*opPtr = '\0';
	code = Tcl_GetInt(interp, bytes, &first);
	*opPtr = savedOp;
	if (code == TCL_ERROR) {
	    goto parseError;
	}
	if (TCL_ERROR == Tcl_GetInt(interp, opPtr+1, &second)) {
	    goto parseError;
	}
	if (savedOp == '+') {
	    *indexPtr = first + second;
	} else {
	    *indexPtr = first - second;
	}
	return TCL_OK;
    }

    /*
     * Report a parse error.
     */

  parseError:
    if (interp != NULL) {
	char *bytes = Tcl_GetString(objPtr);

	/*
	 * The result might not be empty; this resets it which should be both
	 * a cheap operation, and of little problem because this is an
	 * error-generation path anyway.
	 */

	Tcl_ResetResult(interp);
	Tcl_AppendResult(interp, "bad index \"", bytes,
		"\": must be integer?[+-]integer? or end?[+-]integer?", NULL);
	if (!strncmp(bytes, "end-", 4)) {
	    bytes += 4;
	}
	TclCheckBadOctal(interp, bytes);
    }

    return TCL_ERROR;
}

/*
 *----------------------------------------------------------------------
 *
 * UpdateStringOfEndOffset --
 *
 *	Update the string rep of a Tcl object holding an "end-offset"
 *	expression.
 *
 * Results:
 *	None.
 *
 * Side effects:
 *	Stores a valid string in the object's string rep.
 *
 * This function does NOT free any earlier string rep. If it is called on an
 * object that already has a valid string rep, it will leak memory.
 *
 *----------------------------------------------------------------------
 */

static void
UpdateStringOfEndOffset(
    register Tcl_Obj* objPtr)
{
    char buffer[TCL_INTEGER_SPACE + sizeof("end") + 1];
    register int len;

    strcpy(buffer, "end");
    len = sizeof("end") - 1;
    if (objPtr->internalRep.longValue != 0) {
	buffer[len++] = '-';
	len += TclFormatInt(buffer+len, -(objPtr->internalRep.longValue));
    }
    objPtr->bytes = ckalloc((unsigned) len+1);
    memcpy(objPtr->bytes, buffer, (unsigned) len+1);
    objPtr->length = len;
}

/*
 *----------------------------------------------------------------------
 *
 * SetEndOffsetFromAny --
 *
 *	Look for a string of the form "end[+-]offset" and convert it to an
 *	internal representation holding the offset.
 *
 * Results:
 *	Returns TCL_OK if ok, TCL_ERROR if the string was badly formed.
 *
 * Side effects:
 *	If interp is not NULL, stores an error message in the interpreter
 *	result.
 *
 *----------------------------------------------------------------------
 */

static int
SetEndOffsetFromAny(
    Tcl_Interp *interp,		/* Tcl interpreter or NULL */
    Tcl_Obj *objPtr)		/* Pointer to the object to parse */
{
    int offset;			/* Offset in the "end-offset" expression */
    register char* bytes;	/* String rep of the object */
    int length;			/* Length of the object's string rep */

    /*
     * If it's already the right type, we're fine.
     */

    if (objPtr->typePtr == &tclEndOffsetType) {
	return TCL_OK;
    }

    /*
     * Check for a string rep of the right form.
     */

    bytes = TclGetStringFromObj(objPtr, &length);
    if ((*bytes != 'e') || (strncmp(bytes, "end",
	    (size_t)((length > 3) ? 3 : length)) != 0)) {
	if (interp != NULL) {
	    Tcl_ResetResult(interp);
	    Tcl_AppendResult(interp, "bad index \"", bytes,
		    "\": must be end?[+-]integer?", NULL);
	}
	return TCL_ERROR;
    }

    /*
     * Convert the string rep.
     */

    if (length <= 3) {
	offset = 0;
    } else if ((length > 4) && ((bytes[3] == '-') || (bytes[3] == '+'))) {
	/*
	 * This is our limited string expression evaluator. Pass everything
	 * after "end-" to Tcl_GetInt, then reverse for offset.
	 */

	if (TclIsSpaceProc(bytes[4])) {
	    return TCL_ERROR;
	}
	if (Tcl_GetInt(interp, bytes+4, &offset) != TCL_OK) {
	    return TCL_ERROR;
	}
	if (bytes[3] == '-') {
	    offset = -offset;
	}
    } else {
	/*
	 * Conversion failed. Report the error.
	 */

	if (interp != NULL) {
	    Tcl_ResetResult(interp);
	    Tcl_AppendResult(interp, "bad index \"", bytes,
		    "\": must be end?[+-]integer?", NULL);
	}
	return TCL_ERROR;
    }

    /*
     * The conversion succeeded. Free the old internal rep and set the new
     * one.
     */

    TclFreeIntRep(objPtr);
    objPtr->internalRep.longValue = offset;
    objPtr->typePtr = &tclEndOffsetType;

    return TCL_OK;
}

/*
 *----------------------------------------------------------------------
 *
 * TclCheckBadOctal --
 *
 *	This function checks for a bad octal value and appends a meaningful
 *	error to the interp's result.
 *
 * Results:
 *	1 if the argument was a bad octal, else 0.
 *
 * Side effects:
 *	The interpreter's result is modified.
 *
 *----------------------------------------------------------------------
 */

int
TclCheckBadOctal(
    Tcl_Interp *interp,		/* Interpreter to use for error reporting. If
				 * NULL, then no error message is left after
				 * errors. */
    CONST char *value)		/* String to check. */
{
    register CONST char *p = value;

    /*
     * A frequent mistake is invalid octal values due to an unwanted leading
     * zero. Try to generate a meaningful error message.
     */

    while (TclIsSpaceProc(*p)) {
	p++;
    }
    if (*p == '+' || *p == '-') {
	p++;
    }
    if (*p == '0') {
	if ((p[1] == 'o') || p[1] == 'O') {
	    p+=2;
	}
	while (isdigit(UCHAR(*p))) {	/* INTL: digit. */
	    p++;
	}
	while (TclIsSpaceProc(*p)) {
	    p++;
	}
	if (*p == '\0') {
	    /*
	     * Reached end of string.
	     */

	    if (interp != NULL) {
		/*
		 * Don't reset the result here because we want this result to
		 * be added to an existing error message as extra info.
		 */

		Tcl_AppendResult(interp, " (looks like invalid octal number)",
			NULL);
	    }
	    return 1;
	}
    }
    return 0;
}

/*
 *----------------------------------------------------------------------
 *
 * ClearHash --
 *
 *	Remove all the entries in the hash table *tablePtr.
 *
 *----------------------------------------------------------------------
 */

static void
ClearHash(
    Tcl_HashTable *tablePtr)
{
    Tcl_HashSearch search;
    Tcl_HashEntry *hPtr;

    for (hPtr = Tcl_FirstHashEntry(tablePtr, &search); hPtr != NULL;
	    hPtr = Tcl_NextHashEntry(&search)) {
	Tcl_Obj *objPtr = (Tcl_Obj *) Tcl_GetHashValue(hPtr);
	Tcl_DecrRefCount(objPtr);
	Tcl_DeleteHashEntry(hPtr);
    }
}

/*
 *----------------------------------------------------------------------
 *
 * GetThreadHash --
 *
 *	Get a thread-specific (Tcl_HashTable *) associated with a thread data
 *	key.
 *
 * Results:
 *	The Tcl_HashTable * corresponding to *keyPtr.
 *
 * Side effects:
 *	The first call on a keyPtr in each thread creates a new Tcl_HashTable,
 *	and registers a thread exit handler to dispose of it.
 *
 *----------------------------------------------------------------------
 */

static Tcl_HashTable *
GetThreadHash(
    Tcl_ThreadDataKey *keyPtr)
{
    Tcl_HashTable **tablePtrPtr = (Tcl_HashTable **)
	    Tcl_GetThreadData(keyPtr, (int) sizeof(Tcl_HashTable *));

    if (NULL == *tablePtrPtr) {
	*tablePtrPtr = (Tcl_HashTable *)ckalloc(sizeof(Tcl_HashTable));
	Tcl_CreateThreadExitHandler(FreeThreadHash, (ClientData)*tablePtrPtr);
	Tcl_InitHashTable(*tablePtrPtr, TCL_ONE_WORD_KEYS);
    }
    return *tablePtrPtr;
}

/*
 *----------------------------------------------------------------------
 *
 * FreeThreadHash --
 *
 *	Thread exit handler used by GetThreadHash to dispose of a thread hash
 *	table.
 *
 * Side effects:
 *	Frees a Tcl_HashTable.
 *
 *----------------------------------------------------------------------
 */

static void
FreeThreadHash(
    ClientData clientData)
{
    Tcl_HashTable *tablePtr = (Tcl_HashTable *) clientData;

    ClearHash(tablePtr);
    Tcl_DeleteHashTable(tablePtr);
    ckfree((char *) tablePtr);
}

/*
 *----------------------------------------------------------------------
 *
 * FreeProcessGlobalValue --
 *
 *	Exit handler used by Tcl(Set|Get)ProcessGlobalValue to cleanup a
 *	ProcessGlobalValue at exit.
 *
 *----------------------------------------------------------------------
 */

static void
FreeProcessGlobalValue(
    ClientData clientData)
{
    ProcessGlobalValue *pgvPtr = (ProcessGlobalValue *) clientData;

    pgvPtr->epoch++;
    pgvPtr->numBytes = 0;
    ckfree(pgvPtr->value);
    pgvPtr->value = NULL;
    if (pgvPtr->encoding) {
	Tcl_FreeEncoding(pgvPtr->encoding);
	pgvPtr->encoding = NULL;
    }
    Tcl_MutexFinalize(&pgvPtr->mutex);
}

/*
 *----------------------------------------------------------------------
 *
 * TclSetProcessGlobalValue --
 *
 *	Utility routine to set a global value shared by all threads in the
 *	process while keeping a thread-local copy as well.
 *
 *----------------------------------------------------------------------
 */

void
TclSetProcessGlobalValue(
    ProcessGlobalValue *pgvPtr,
    Tcl_Obj *newValue,
    Tcl_Encoding encoding)
{
    CONST char *bytes;
    Tcl_HashTable *cacheMap;
    Tcl_HashEntry *hPtr;
    int dummy;

    Tcl_MutexLock(&pgvPtr->mutex);

    /*
     * Fill the global string value.
     */

    pgvPtr->epoch++;
    if (NULL != pgvPtr->value) {
	ckfree(pgvPtr->value);
    } else {
	Tcl_CreateExitHandler(FreeProcessGlobalValue, (ClientData) pgvPtr);
    }
    bytes = Tcl_GetStringFromObj(newValue, &pgvPtr->numBytes);
    pgvPtr->value = ckalloc((unsigned) pgvPtr->numBytes + 1);
    memcpy(pgvPtr->value, bytes, (unsigned) pgvPtr->numBytes + 1);
    if (pgvPtr->encoding) {
	Tcl_FreeEncoding(pgvPtr->encoding);
    }
    pgvPtr->encoding = encoding;

    /*
     * Fill the local thread copy directly with the Tcl_Obj value to avoid
     * loss of the intrep. Increment newValue refCount early to handle case
     * where we set a PGV to itself.
     */

    Tcl_IncrRefCount(newValue);
    cacheMap = GetThreadHash(&pgvPtr->key);
    ClearHash(cacheMap);
    hPtr = Tcl_CreateHashEntry(cacheMap,
	    (char *) INT2PTR(pgvPtr->epoch), &dummy);
    Tcl_SetHashValue(hPtr, (ClientData) newValue);
    Tcl_MutexUnlock(&pgvPtr->mutex);
}

/*
 *----------------------------------------------------------------------
 *
 * TclGetProcessGlobalValue --
 *
 *	Retrieve a global value shared among all threads of the process,
 *	preferring a thread-local copy as long as it remains valid.
 *
 * Results:
 *	Returns a (Tcl_Obj *) that holds a copy of the global value.
 *
 *----------------------------------------------------------------------
 */

Tcl_Obj *
TclGetProcessGlobalValue(
    ProcessGlobalValue *pgvPtr)
{
    Tcl_Obj *value = NULL;
    Tcl_HashTable *cacheMap;
    Tcl_HashEntry *hPtr;
    int epoch = pgvPtr->epoch;

    if (pgvPtr->encoding) {
	Tcl_Encoding current = Tcl_GetEncoding(NULL, NULL);

	if (pgvPtr->encoding != current) {
	    /*
	     * The system encoding has changed since the master string value
	     * was saved. Convert the master value to be based on the new
	     * system encoding.
	     */

	    Tcl_DString native, newValue;

	    Tcl_MutexLock(&pgvPtr->mutex);
	    pgvPtr->epoch++;
	    epoch = pgvPtr->epoch;
	    Tcl_UtfToExternalDString(pgvPtr->encoding, pgvPtr->value,
		    pgvPtr->numBytes, &native);
	    Tcl_ExternalToUtfDString(current, Tcl_DStringValue(&native),
	    Tcl_DStringLength(&native), &newValue);
	    Tcl_DStringFree(&native);
	    ckfree(pgvPtr->value);
	    pgvPtr->value = ckalloc((unsigned int)
		    Tcl_DStringLength(&newValue) + 1);
	    memcpy(pgvPtr->value, Tcl_DStringValue(&newValue),
		    (size_t) Tcl_DStringLength(&newValue) + 1);
	    Tcl_DStringFree(&newValue);
	    Tcl_FreeEncoding(pgvPtr->encoding);
	    pgvPtr->encoding = current;
	    Tcl_MutexUnlock(&pgvPtr->mutex);
	} else {
	    Tcl_FreeEncoding(current);
	}
    }
    cacheMap = GetThreadHash(&pgvPtr->key);
    hPtr = Tcl_FindHashEntry(cacheMap, (char *) INT2PTR(epoch));
    if (NULL == hPtr) {
	int dummy;

	/*
	 * No cache for the current epoch - must be a new one.
	 *
	 * First, clear the cacheMap, as anything in it must refer to some
	 * expired epoch.
	 */

	ClearHash(cacheMap);

	/*
	 * If no thread has set the shared value, call the initializer.
	 */

	Tcl_MutexLock(&pgvPtr->mutex);
	if ((NULL == pgvPtr->value) && (pgvPtr->proc)) {
	    pgvPtr->epoch++;
	    (*(pgvPtr->proc))(&pgvPtr->value, &pgvPtr->numBytes,
		    &pgvPtr->encoding);
	    if (pgvPtr->value == NULL) {
		Tcl_Panic("PGV Initializer did not initialize");
	    }
	    Tcl_CreateExitHandler(FreeProcessGlobalValue, (ClientData)pgvPtr);
	}

	/*
	 * Store a copy of the shared value in our epoch-indexed cache.
	 */

	value = Tcl_NewStringObj(pgvPtr->value, pgvPtr->numBytes);
	hPtr = Tcl_CreateHashEntry(cacheMap,
		(char *) INT2PTR(pgvPtr->epoch), &dummy);
	Tcl_MutexUnlock(&pgvPtr->mutex);
	Tcl_SetHashValue(hPtr, (ClientData) value);
	Tcl_IncrRefCount(value);
    }
    return (Tcl_Obj *) Tcl_GetHashValue(hPtr);
}

/*
 *----------------------------------------------------------------------
 *
 * TclSetObjNameOfExecutable --
 *
 *	This function stores the absolute pathname of the executable file
 *	(normally as computed by TclpFindExecutable).
 *
 * Results:
 * 	None.
 *
 * Side effects:
 *	Stores the executable name.
 *
 *----------------------------------------------------------------------
 */

void
TclSetObjNameOfExecutable(
    Tcl_Obj *name,
    Tcl_Encoding encoding)
{
    TclSetProcessGlobalValue(&executableName, name, encoding);
}

/*
 *----------------------------------------------------------------------
 *
 * TclGetObjNameOfExecutable --
 *
 *	This function retrieves the absolute pathname of the application in
 *	which the Tcl library is running, usually as previously stored by
 *	TclpFindExecutable(). This function call is the C API equivalent to
 *	the "info nameofexecutable" command.
 *
 * Results:
 *	A pointer to an "fsPath" Tcl_Obj, or to an empty Tcl_Obj if the
 *	pathname of the application is unknown.
 *
 * Side effects:
 * 	None.
 *
 *----------------------------------------------------------------------
 */

Tcl_Obj *
TclGetObjNameOfExecutable(void)
{
    return TclGetProcessGlobalValue(&executableName);
}

/*
 *----------------------------------------------------------------------
 *
 * Tcl_GetNameOfExecutable --
 *
 *	This function retrieves the absolute pathname of the application in
 *	which the Tcl library is running, and returns it in string form.
 *
 * 	The returned string belongs to Tcl and should be copied if the caller
 * 	plans to keep it, to guard against it becoming invalid.
 *
 * Results:
 *	A pointer to the internal string or NULL if the internal full path
 *	name has not been computed or unknown.
 *
 * Side effects:
 * 	None.
 *
 *----------------------------------------------------------------------
 */

CONST char *
Tcl_GetNameOfExecutable(void)
{
    int numBytes;
    const char *bytes =
	    Tcl_GetStringFromObj(TclGetObjNameOfExecutable(), &numBytes);

    if (numBytes == 0) {
	return NULL;
    }
    return bytes;
}

/*
 *----------------------------------------------------------------------
 *
 * TclpGetTime --
 *
 *	Deprecated synonym for Tcl_GetTime. This function is provided for the
 *	benefit of extensions written before Tcl_GetTime was exported from the
 *	library.
 *
 * Results:
 *	None.
 *
 * Side effects:
 *	Stores current time in the buffer designated by "timePtr"
 *
 *----------------------------------------------------------------------
 */

void
TclpGetTime(
    Tcl_Time *timePtr)
{
    Tcl_GetTime(timePtr);
}

/*
 *----------------------------------------------------------------------
 *
 * TclGetPlatform --
 *
 *	This is a kludge that allows the test library to get access the
 *	internal tclPlatform variable.
 *
 * Results:
 *	Returns a pointer to the tclPlatform variable.
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

TclPlatformType *
TclGetPlatform(void)
{
    return &tclPlatform;
}

/*
 *----------------------------------------------------------------------
 *
 * TclReToGlob --
 *
 *	Attempt to convert a regular expression to an equivalent glob pattern.
 *
 * Results:
 *	Returns TCL_OK on success, TCL_ERROR on failure. If interp is not
 *	NULL, an error message is placed in the result. On success, the
 *	DString will contain an exact equivalent glob pattern. The caller is
 *	responsible for calling Tcl_DStringFree on success. If exactPtr is not
 *	NULL, it will be 1 if an exact match qualifies.
 *
 * Side effects:
 *	None.
 *
 *----------------------------------------------------------------------
 */

int
TclReToGlob(
    Tcl_Interp *interp,
    const char *reStr,
    int reStrLen,
    Tcl_DString *dsPtr,
    int *exactPtr)
{
    int anchorLeft, anchorRight, lastIsStar, numStars;
    char *dsStr, *dsStrStart, *msg;
    const char *p, *strEnd;

    strEnd = reStr + reStrLen;
    Tcl_DStringInit(dsPtr);

    /*
     * "***=xxx" == "*xxx*", watch for glob-sensitive chars.
     */

    if ((reStrLen >= 4) && (memcmp("***=", reStr, 4) == 0)) {
	/*
	 * At most, the glob pattern has length 2*reStrLen + 2 to
	 * backslash escape every character and have * at each end.
	 */
	Tcl_DStringSetLength(dsPtr, 2*reStrLen + 2);
	dsStr = dsStrStart = Tcl_DStringValue(dsPtr);
	*dsStr++ = '*';
	for (p = reStr + 4; p < strEnd; p++) {
	    switch (*p) {
	    case '\\': case '*': case '[': case ']': case '?':
		/* Only add \ where necessary for glob */
		*dsStr++ = '\\';
		/* fall through */
	    default:
		*dsStr++ = *p;
		break;
	    }
	}
	*dsStr++ = '*';
	Tcl_DStringSetLength(dsPtr, dsStr - dsStrStart);
	if (exactPtr) {
	    *exactPtr = 0;
	}
	return TCL_OK;
    }

    /*
     * At most, the glob pattern has length reStrLen + 2 to account
     * for possible * at each end.
     */

    Tcl_DStringSetLength(dsPtr, reStrLen + 2);
    dsStr = dsStrStart = Tcl_DStringValue(dsPtr);

    /*
     * Check for anchored REs (ie ^foo$), so we can use string equal if
     * possible. Do not alter the start of str so we can free it correctly.
     *
     * Keep track of the last char being an unescaped star to prevent
     * multiple instances.  Simpler than checking that the last star
     * may be escaped.
     */

    msg = NULL;
    p = reStr;
    anchorRight = 0;
    lastIsStar = 0;
    numStars = 0;

    if (*p == '^') {
	anchorLeft = 1;
	p++;
    } else {
	anchorLeft = 0;
	*dsStr++ = '*';
	lastIsStar = 1;
    }

    for ( ; p < strEnd; p++) {
	switch (*p) {
	case '\\':
	    p++;
	    switch (*p) {
	    case 'a':
		*dsStr++ = '\a';
		break;
	    case 'b':
		*dsStr++ = '\b';
		break;
	    case 'f':
		*dsStr++ = '\f';
		break;
	    case 'n':
		*dsStr++ = '\n';
		break;
	    case 'r':
		*dsStr++ = '\r';
		break;
	    case 't':
		*dsStr++ = '\t';
		break;
	    case 'v':
		*dsStr++ = '\v';
		break;
	    case 'B': case '\\':
		*dsStr++ = '\\';
		*dsStr++ = '\\';
		anchorLeft = 0; /* prevent exact match */
		break;
	    case '*': case '[': case ']': case '?':
		/* Only add \ where necessary for glob */
		*dsStr++ = '\\';
		anchorLeft = 0; /* prevent exact match */
		/* fall through */
	    case '{': case '}': case '(': case ')': case '+':
	    case '.': case '|': case '^': case '$':
		*dsStr++ = *p;
		break;
	    default:
		msg = "invalid escape sequence";
		goto invalidGlob;
	    }
	    break;
	case '.':
	    anchorLeft = 0; /* prevent exact match */
	    if (p+1 < strEnd) {
		if (p[1] == '*') {
		    p++;
		    if (!lastIsStar) {
			*dsStr++ = '*';
			lastIsStar = 1;
			numStars++;
		    }
		    continue;
		} else if (p[1] == '+') {
		    p++;
		    *dsStr++ = '?';
		    *dsStr++ = '*';
		    lastIsStar = 1;
		    numStars++;
		    continue;
		}
	    }
	    *dsStr++ = '?';
	    break;
	case '$':
	    if (p+1 != strEnd) {
		msg = "$ not anchor";
		goto invalidGlob;
	    }
	    anchorRight = 1;
	    break;
	case '*': case '+': case '?': case '|': case '^':
	case '{': case '}': case '(': case ')': case '[': case ']':
	    msg = "unhandled RE special char";
	    goto invalidGlob;
	    break;
	default:
	    *dsStr++ = *p;
	    break;
	}
	lastIsStar = 0;
    }
    if (numStars > 1) {
	/*
	 * Heuristic: if >1 non-anchoring *, the risk is large that glob
	 * matching is slower than the RE engine, so report invalid.
	 */
	msg = "excessive recursive glob backtrack potential";
	goto invalidGlob;
    }

    if (!anchorRight && !lastIsStar) {
	*dsStr++ = '*';
    }
    Tcl_DStringSetLength(dsPtr, dsStr - dsStrStart);

    if (exactPtr) {
	*exactPtr = (anchorLeft && anchorRight);
    }

#if 0
    fprintf(stderr, "INPUT RE '%.*s' OUTPUT GLOB '%s' anchor %d:%d \n",
	    reStrLen, reStr,
	    Tcl_DStringValue(dsPtr), anchorLeft, anchorRight);
    fflush(stderr);
#endif
    return TCL_OK;

  invalidGlob:
#if 0
    fprintf(stderr, "INPUT RE '%.*s' NO OUTPUT GLOB %s (%c)\n",
	    reStrLen, reStr, msg, *p);
    fflush(stderr);
#endif
    if (interp != NULL) {
	Tcl_AppendResult(interp, msg, NULL);
    }
    Tcl_DStringFree(dsPtr);
    return TCL_ERROR;
}

/*
 * Local Variables:
 * mode: c
 * c-basic-offset: 4
 * fill-column: 78
 * End:
 */