coreutils/expr.c - busybox - Git at Google

 /* vi: set sw=4 ts=4: */
 /*
  * Mini expr implementation for busybox
  *
  * based on GNU expr Mike Parker.
  * Copyright (C) 86, 1991-1997, 1999 Free Software Foundation, Inc.
  *
  * Busybox modifications
  * Copyright (c) 2000  Edward Betts <edward@debian.org>.
  * Copyright (C) 2003-2005  Vladimir Oleynik <dzo@simtreas.ru>
  *  - reduced 464 bytes.
  *  - 64 math support
  *
  * Licensed under GPLv2 or later, see file LICENSE in this source tree.
  */

 /* This program evaluates expressions.  Each token (operator, operand,
  * parenthesis) of the expression must be a separate argument.  The
  * parser used is a reasonably general one, though any incarnation of
  * it is language-specific.  It is especially nice for expressions.
  *
  * No parse tree is needed; a new node is evaluated immediately.
  * One function can handle multiple operators all of equal precedence,
  * provided they all associate ((x op x) op x). */

 /* no getopt needed */

 //usage:#define expr_trivial_usage
 //usage:       "EXPRESSION"
 //usage:#define expr_full_usage "\n\n"
 //usage:       "Print the value of EXPRESSION to stdout\n"
 //usage:    "\n"
 //usage:       "EXPRESSION may be:\n"
 //usage:       "	ARG1 | ARG2	ARG1 if it is neither null nor 0, otherwise ARG2\n"
 //usage:       "	ARG1 & ARG2	ARG1 if neither argument is null or 0, otherwise 0\n"
 //usage:       "	ARG1 < ARG2	1 if ARG1 is less than ARG2, else 0. Similarly:\n"
 //usage:       "	ARG1 <= ARG2\n"
 //usage:       "	ARG1 = ARG2\n"
 //usage:       "	ARG1 != ARG2\n"
 //usage:       "	ARG1 >= ARG2\n"
 //usage:       "	ARG1 > ARG2\n"
 //usage:       "	ARG1 + ARG2	Sum of ARG1 and ARG2. Similarly:\n"
 //usage:       "	ARG1 - ARG2\n"
 //usage:       "	ARG1 * ARG2\n"
 //usage:       "	ARG1 / ARG2\n"
 //usage:       "	ARG1 % ARG2\n"
 //usage:       "	STRING : REGEXP		Anchored pattern match of REGEXP in STRING\n"
 //usage:       "	match STRING REGEXP	Same as STRING : REGEXP\n"
 //usage:       "	substr STRING POS LENGTH Substring of STRING, POS counted from 1\n"
 //usage:       "	index STRING CHARS	Index in STRING where any CHARS is found, or 0\n"
 //usage:       "	length STRING		Length of STRING\n"
 //usage:       "	quote TOKEN		Interpret TOKEN as a string, even if\n"
 //usage:       "				it is a keyword like 'match' or an\n"
 //usage:       "				operator like '/'\n"
 //usage:       "	(EXPRESSION)		Value of EXPRESSION\n"
 //usage:       "\n"
 //usage:       "Beware that many operators need to be escaped or quoted for shells.\n"
 //usage:       "Comparisons are arithmetic if both ARGs are numbers, else\n"
 //usage:       "lexicographical. Pattern matches return the string matched between\n"
 //usage:       "\\( and \\) or null; if \\( and \\) are not used, they return the number\n"
 //usage:       "of characters matched or 0."

 #include "libbb.h"
 #include "xregex.h"

 #if ENABLE_EXPR_MATH_SUPPORT_64
 typedef int64_t arith_t;

 #define PF_REZ      "ll"
 #define PF_REZ_TYPE (long long)
 #define STRTOL(s, e, b) strtoll(s, e, b)
 #else
 typedef long arith_t;

 #define PF_REZ      "l"
 #define PF_REZ_TYPE (long)
 #define STRTOL(s, e, b) strtol(s, e, b)
 #endif

 /* TODO: use bb_strtol[l]? It's easier to check for errors... */

 /* The kinds of value we can have.  */
 enum {
 	INTEGER,
 	STRING
 };

 /* A value is.... */
 struct valinfo {
 	smallint type;                  /* Which kind. */
 	union {                         /* The value itself. */
 		arith_t i;
 		char *s;
 	} u;
 };
 typedef struct valinfo VALUE;

 /* The arguments given to the program, minus the program name.  */
 struct globals {
 	char **args;
 } FIX_ALIASING;
 #define G (*(struct globals*)&bb_common_bufsiz1)
 #define INIT_G() do { } while (0)

 /* forward declarations */
 static VALUE *eval(void);


 /* Return a VALUE for I.  */

 static VALUE *int_value(arith_t i)
 {
 	VALUE *v;

 	v = xzalloc(sizeof(VALUE));
 	if (INTEGER) /* otherwise xzaaloc did it already */
 		v->type = INTEGER;
 	v->u.i = i;
 	return v;
 }

 /* Return a VALUE for S.  */

 static VALUE *str_value(const char *s)
 {
 	VALUE *v;

 	v = xzalloc(sizeof(VALUE));
 	if (STRING) /* otherwise xzaaloc did it already */
 		v->type = STRING;
 	v->u.s = xstrdup(s);
 	return v;
 }

 /* Free VALUE V, including structure components.  */

 static void freev(VALUE *v)
 {
 	if (v->type == STRING)
 		free(v->u.s);
 	free(v);
 }

 /* Return nonzero if V is a null-string or zero-number.  */

 static int null(VALUE *v)
 {
 	if (v->type == INTEGER)
 		return v->u.i == 0;
 	/* STRING: */
 	return v->u.s[0] == '\0' || LONE_CHAR(v->u.s, '0');
 }

 /* Coerce V to a STRING value (can't fail).  */

 static void tostring(VALUE *v)
 {
 	if (v->type == INTEGER) {
 		v->u.s = xasprintf("%" PF_REZ "d", PF_REZ_TYPE v->u.i);
 		v->type = STRING;
 	}
 }

 /* Coerce V to an INTEGER value.  Return 1 on success, 0 on failure.  */

 static bool toarith(VALUE *v)
 {
 	if (v->type == STRING) {
 		arith_t i;
 		char *e;

 		/* Don't interpret the empty string as an integer.  */
 		/* Currently does not worry about overflow or int/long differences. */
 		i = STRTOL(v->u.s, &e, 10);
 		if ((v->u.s == e) || *e)
 			return 0;
 		free(v->u.s);
 		v->u.i = i;
 		v->type = INTEGER;
 	}
 	return 1;
 }

 /* Return str[0]+str[1] if the next token matches STR exactly.
    STR must not be NULL.  */

 static int nextarg(const char *str)
 {
 	if (*G.args == NULL || strcmp(*G.args, str) != 0)
 		return 0;
 	return (unsigned char)str[0] + (unsigned char)str[1];
 }

 /* The comparison operator handling functions.  */

 static int cmp_common(VALUE *l, VALUE *r, int op)
 {
 	arith_t ll, rr;

 	ll = l->u.i;
 	rr = r->u.i;
 	if (l->type == STRING || r->type == STRING) {
 		tostring(l);
 		tostring(r);
 		ll = strcmp(l->u.s, r->u.s);
 		rr = 0;
 	}
 	/* calculating ll - rr and checking the result is prone to overflows.
 	 * We'll do it differently: */
 	if (op == '<')
 		return ll < rr;
 	if (op == ('<' + '='))
 		return ll <= rr;
 	if (op == '=' || (op == '=' + '='))
 		return ll == rr;
 	if (op == '!' + '=')
 		return ll != rr;
 	if (op == '>')
 		return ll > rr;
 	/* >= */
 	return ll >= rr;
 }

 /* The arithmetic operator handling functions.  */

 static arith_t arithmetic_common(VALUE *l, VALUE *r, int op)
 {
 	arith_t li, ri;

 	if (!toarith(l) || !toarith(r))
 		bb_error_msg_and_die("non-numeric argument");
 	li = l->u.i;
 	ri = r->u.i;
 	if (op == '+')
 		return li + ri;
 	if (op == '-')
 		return li - ri;
 	if (op == '*')
 		return li * ri;
 	if (ri == 0)
 		bb_error_msg_and_die("division by zero");
 	if (op == '/')
 		return li / ri;
 	return li % ri;
 }

 /* Do the : operator.
    SV is the VALUE for the lhs (the string),
    PV is the VALUE for the rhs (the pattern).  */

 static VALUE *docolon(VALUE *sv, VALUE *pv)
 {
 	enum { NMATCH = 2 };
 	VALUE *v;
 	regex_t re_buffer;
 	regmatch_t re_regs[NMATCH];

 	tostring(sv);
 	tostring(pv);

 	if (pv->u.s[0] == '^') {
 		bb_error_msg(
 "warning: '%s': using '^' as the first character\n"
 "of a basic regular expression is not portable; it is ignored", pv->u.s);
 	}

 	memset(&re_buffer, 0, sizeof(re_buffer));
 	memset(re_regs, 0, sizeof(re_regs));
 	xregcomp(&re_buffer, pv->u.s, 0);

 	/* expr uses an anchored pattern match, so check that there was a
 	 * match and that the match starts at offset 0. */
 	if (regexec(&re_buffer, sv->u.s, NMATCH, re_regs, 0) != REG_NOMATCH
 	 && re_regs[0].rm_so == 0
 	) {
 		/* Were \(...\) used? */
 		if (re_buffer.re_nsub > 0 && re_regs[1].rm_so >= 0) {
 			sv->u.s[re_regs[1].rm_eo] = '\0';
 			v = str_value(sv->u.s + re_regs[1].rm_so);
 		} else {
 			v = int_value(re_regs[0].rm_eo);
 		}
 	} else {
 		/* Match failed -- return the right kind of null.  */
 		if (re_buffer.re_nsub > 0)
 			v = str_value("");
 		else
 			v = int_value(0);
 	}
 	regfree(&re_buffer);
 	return v;
 }

 /* Handle bare operands and ( expr ) syntax.  */

 static VALUE *eval7(void)
 {
 	VALUE *v;

 	if (!*G.args)
 		bb_error_msg_and_die("syntax error");

 	if (nextarg("(")) {
 		G.args++;
 		v = eval();
 		if (!nextarg(")"))
 			bb_error_msg_and_die("syntax error");
 		G.args++;
 		return v;
 	}

 	if (nextarg(")"))
 		bb_error_msg_and_die("syntax error");

 	return str_value(*G.args++);
 }

 /* Handle match, substr, index, length, and quote keywords.  */

 static VALUE *eval6(void)
 {
 	static const char keywords[] ALIGN1 =
 		"quote\0""length\0""match\0""index\0""substr\0";

 	VALUE *r, *i1, *i2;
 	VALUE *l = l; /* silence gcc */
 	VALUE *v = v; /* silence gcc */
 	int key = *G.args ? index_in_strings(keywords, *G.args) + 1 : 0;

 	if (key == 0) /* not a keyword */
 		return eval7();
 	G.args++; /* We have a valid token, so get the next argument.  */
 	if (key == 1) { /* quote */
 		if (!*G.args)
 			bb_error_msg_and_die("syntax error");
 		return str_value(*G.args++);
 	}
 	if (key == 2) { /* length */
 		r = eval6();
 		tostring(r);
 		v = int_value(strlen(r->u.s));
 		freev(r);
 	} else
 		l = eval6();

 	if (key == 3) { /* match */
 		r = eval6();
 		v = docolon(l, r);
 		freev(l);
 		freev(r);
 	}
 	if (key == 4) { /* index */
 		r = eval6();
 		tostring(l);
 		tostring(r);
 		v = int_value(strcspn(l->u.s, r->u.s) + 1);
 		if (v->u.i == (arith_t) strlen(l->u.s) + 1)
 			v->u.i = 0;
 		freev(l);
 		freev(r);
 	}
 	if (key == 5) { /* substr */
 		i1 = eval6();
 		i2 = eval6();
 		tostring(l);
 		if (!toarith(i1) || !toarith(i2)
 		 || i1->u.i > (arith_t) strlen(l->u.s)
 		 || i1->u.i <= 0 || i2->u.i <= 0)
 			v = str_value("");
 		else {
 			v = xmalloc(sizeof(VALUE));
 			v->type = STRING;
 			v->u.s = xstrndup(l->u.s + i1->u.i - 1, i2->u.i);
 		}
 		freev(l);
 		freev(i1);
 		freev(i2);
 	}
 	return v;
 }

 /* Handle : operator (pattern matching).
    Calls docolon to do the real work.  */

 static VALUE *eval5(void)
 {
 	VALUE *l, *r, *v;

 	l = eval6();
 	while (nextarg(":")) {
 		G.args++;
 		r = eval6();
 		v = docolon(l, r);
 		freev(l);
 		freev(r);
 		l = v;
 	}
 	return l;
 }

 /* Handle *, /, % operators.  */

 static VALUE *eval4(void)
 {
 	VALUE *l, *r;
 	int op;
 	arith_t val;

 	l = eval5();
 	while (1) {
 		op = nextarg("*");
 		if (!op) { op = nextarg("/");
 		 if (!op) { op = nextarg("%");
 		  if (!op) return l;
 		}}
 		G.args++;
 		r = eval5();
 		val = arithmetic_common(l, r, op);
 		freev(l);
 		freev(r);
 		l = int_value(val);
 	}
 }

 /* Handle +, - operators.  */

 static VALUE *eval3(void)
 {
 	VALUE *l, *r;
 	int op;
 	arith_t val;

 	l = eval4();
 	while (1) {
 		op = nextarg("+");
 		if (!op) {
 			op = nextarg("-");
 			if (!op) return l;
 		}
 		G.args++;
 		r = eval4();
 		val = arithmetic_common(l, r, op);
 		freev(l);
 		freev(r);
 		l = int_value(val);
 	}
 }

 /* Handle comparisons.  */

 static VALUE *eval2(void)
 {
 	VALUE *l, *r;
 	int op;
 	arith_t val;

 	l = eval3();
 	while (1) {
 		op = nextarg("<");
 		if (!op) { op = nextarg("<=");
 		 if (!op) { op = nextarg("=");
 		  if (!op) { op = nextarg("==");
 		   if (!op) { op = nextarg("!=");
 		    if (!op) { op = nextarg(">=");
 		     if (!op) { op = nextarg(">");
 		      if (!op) return l;
 		}}}}}}
 		G.args++;
 		r = eval3();
 		toarith(l);
 		toarith(r);
 		val = cmp_common(l, r, op);
 		freev(l);
 		freev(r);
 		l = int_value(val);
 	}
 }

 /* Handle &.  */

 static VALUE *eval1(void)
 {
 	VALUE *l, *r;

 	l = eval2();
 	while (nextarg("&")) {
 		G.args++;
 		r = eval2();
 		if (null(l) || null(r)) {
 			freev(l);
 			freev(r);
 			l = int_value(0);
 		} else
 			freev(r);
 	}
 	return l;
 }

 /* Handle |.  */

 static VALUE *eval(void)
 {
 	VALUE *l, *r;

 	l = eval1();
 	while (nextarg("|")) {
 		G.args++;
 		r = eval1();
 		if (null(l)) {
 			freev(l);
 			l = r;
 		} else
 			freev(r);
 	}
 	return l;
 }

 int expr_main(int argc, char **argv) MAIN_EXTERNALLY_VISIBLE;
 int expr_main(int argc UNUSED_PARAM, char **argv)
 {
 	VALUE *v;

 	INIT_G();

 	xfunc_error_retval = 2; /* coreutils compat */
 	G.args = argv + 1;
 	if (*G.args == NULL) {
 		bb_error_msg_and_die("too few arguments");
 	}
 	v = eval();
 	if (*G.args)
 		bb_error_msg_and_die("syntax error");
 	if (v->type == INTEGER)
 		printf("%" PF_REZ "d\n", PF_REZ_TYPE v->u.i);
 	else
 		puts(v->u.s);
 	fflush_stdout_and_exit(null(v));
 }
	/* vi: set sw=4 ts=4: */
	/*
	* Mini expr implementation for busybox
	*
	* based on GNU expr Mike Parker.
	* Copyright (C) 86, 1991-1997, 1999 Free Software Foundation, Inc.
	*
	* Busybox modifications
	* Copyright (c) 2000 Edward Betts <edward@debian.org>.
	* Copyright (C) 2003-2005 Vladimir Oleynik <dzo@simtreas.ru>
	* - reduced 464 bytes.
	* - 64 math support
	*
	* Licensed under GPLv2 or later, see file LICENSE in this source tree.
	*/

	/* This program evaluates expressions. Each token (operator, operand,
	* parenthesis) of the expression must be a separate argument. The
	* parser used is a reasonably general one, though any incarnation of
	* it is language-specific. It is especially nice for expressions.
	*
	* No parse tree is needed; a new node is evaluated immediately.
	* One function can handle multiple operators all of equal precedence,
	* provided they all associate ((x op x) op x). */

	/* no getopt needed */

	//usage:#define expr_trivial_usage
	//usage: "EXPRESSION"
	//usage:#define expr_full_usage "\n\n"
	//usage: "Print the value of EXPRESSION to stdout\n"
	//usage: "\n"
	//usage: "EXPRESSION may be:\n"
	//usage: " ARG1 \| ARG2 ARG1 if it is neither null nor 0, otherwise ARG2\n"
	//usage: " ARG1 & ARG2 ARG1 if neither argument is null or 0, otherwise 0\n"
	//usage: " ARG1 < ARG2 1 if ARG1 is less than ARG2, else 0. Similarly:\n"
	//usage: " ARG1 <= ARG2\n"
	//usage: " ARG1 = ARG2\n"
	//usage: " ARG1 != ARG2\n"
	//usage: " ARG1 >= ARG2\n"
	//usage: " ARG1 > ARG2\n"
	//usage: " ARG1 + ARG2 Sum of ARG1 and ARG2. Similarly:\n"
	//usage: " ARG1 - ARG2\n"
	//usage: " ARG1 * ARG2\n"
	//usage: " ARG1 / ARG2\n"
	//usage: " ARG1 % ARG2\n"
	//usage: " STRING : REGEXP Anchored pattern match of REGEXP in STRING\n"
	//usage: " match STRING REGEXP Same as STRING : REGEXP\n"
	//usage: " substr STRING POS LENGTH Substring of STRING, POS counted from 1\n"
	//usage: " index STRING CHARS Index in STRING where any CHARS is found, or 0\n"
	//usage: " length STRING Length of STRING\n"
	//usage: " quote TOKEN Interpret TOKEN as a string, even if\n"
	//usage: " it is a keyword like 'match' or an\n"
	//usage: " operator like '/'\n"
	//usage: " (EXPRESSION) Value of EXPRESSION\n"
	//usage: "\n"
	//usage: "Beware that many operators need to be escaped or quoted for shells.\n"
	//usage: "Comparisons are arithmetic if both ARGs are numbers, else\n"
	//usage: "lexicographical. Pattern matches return the string matched between\n"
	//usage: "\\( and \\) or null; if \\( and \\) are not used, they return the number\n"
	//usage: "of characters matched or 0."

	#include "libbb.h"
	#include "xregex.h"

	#if ENABLE_EXPR_MATH_SUPPORT_64
	typedef int64_t arith_t;

	#define PF_REZ "ll"
	#define PF_REZ_TYPE (long long)
	#define STRTOL(s, e, b) strtoll(s, e, b)
	#else
	typedef long arith_t;

	#define PF_REZ "l"
	#define PF_REZ_TYPE (long)
	#define STRTOL(s, e, b) strtol(s, e, b)
	#endif

	/* TODO: use bb_strtol[l]? It's easier to check for errors... */

	/* The kinds of value we can have. */
	enum {
	INTEGER,
	STRING
	};

	/* A value is.... */
	struct valinfo {
	smallint type; /* Which kind. */
	union { /* The value itself. */
	arith_t i;
	char *s;
	} u;
	};
	typedef struct valinfo VALUE;

	/* The arguments given to the program, minus the program name. */
	struct globals {
	char **args;
	} FIX_ALIASING;
	#define G ((struct globals)&bb_common_bufsiz1)
	#define INIT_G() do { } while (0)

	/* forward declarations */
	static VALUE *eval(void);


	/* Return a VALUE for I. */

	static VALUE *int_value(arith_t i)
	{
	VALUE *v;

	v = xzalloc(sizeof(VALUE));
	if (INTEGER) /* otherwise xzaaloc did it already */
	v->type = INTEGER;
	v->u.i = i;
	return v;
	}

	/* Return a VALUE for S. */

	static VALUE str_value(const char s)
	{
	VALUE *v;

	v = xzalloc(sizeof(VALUE));
	if (STRING) /* otherwise xzaaloc did it already */
	v->type = STRING;
	v->u.s = xstrdup(s);
	return v;
	}

	/* Free VALUE V, including structure components. */

	static void freev(VALUE *v)
	{
	if (v->type == STRING)
	free(v->u.s);
	free(v);
	}

	/* Return nonzero if V is a null-string or zero-number. */

	static int null(VALUE *v)
	{
	if (v->type == INTEGER)
	return v->u.i == 0;
	/* STRING: */
	return v->u.s[0] == '\0' \|\| LONE_CHAR(v->u.s, '0');
	}

	/* Coerce V to a STRING value (can't fail). */

	static void tostring(VALUE *v)
	{
	if (v->type == INTEGER) {
	v->u.s = xasprintf("%" PF_REZ "d", PF_REZ_TYPE v->u.i);
	v->type = STRING;
	}
	}

	/* Coerce V to an INTEGER value. Return 1 on success, 0 on failure. */

	static bool toarith(VALUE *v)
	{
	if (v->type == STRING) {
	arith_t i;
	char *e;

	/* Don't interpret the empty string as an integer. */
	/* Currently does not worry about overflow or int/long differences. */
	i = STRTOL(v->u.s, &e, 10);
	if ((v->u.s == e) \|\| *e)
	return 0;
	free(v->u.s);
	v->u.i = i;
	v->type = INTEGER;
	}
	return 1;
	}

	/* Return str[0]+str[1] if the next token matches STR exactly.
	STR must not be NULL. */

	static int nextarg(const char *str)
	{
	if (G.args == NULL \|\| strcmp(G.args, str) != 0)
	return 0;
	return (unsigned char)str[0] + (unsigned char)str[1];
	}

	/* The comparison operator handling functions. */

	static int cmp_common(VALUE l, VALUE r, int op)
	{
	arith_t ll, rr;

	ll = l->u.i;
	rr = r->u.i;
	if (l->type == STRING \|\| r->type == STRING) {
	tostring(l);
	tostring(r);
	ll = strcmp(l->u.s, r->u.s);
	rr = 0;
	}
	/* calculating ll - rr and checking the result is prone to overflows.
	* We'll do it differently: */
	if (op == '<')
	return ll < rr;
	if (op == ('<' + '='))
	return ll <= rr;
	if (op == '=' \|\| (op == '=' + '='))
	return ll == rr;
	if (op == '!' + '=')
	return ll != rr;
	if (op == '>')
	return ll > rr;
	/* >= */
	return ll >= rr;
	}

	/* The arithmetic operator handling functions. */

	static arith_t arithmetic_common(VALUE l, VALUE r, int op)
	{
	arith_t li, ri;

	if (!toarith(l) \|\| !toarith(r))
	bb_error_msg_and_die("non-numeric argument");
	li = l->u.i;
	ri = r->u.i;
	if (op == '+')
	return li + ri;
	if (op == '-')
	return li - ri;
	if (op == '*')
	return li * ri;
	if (ri == 0)
	bb_error_msg_and_die("division by zero");
	if (op == '/')
	return li / ri;
	return li % ri;
	}

	/* Do the : operator.
	SV is the VALUE for the lhs (the string),
	PV is the VALUE for the rhs (the pattern). */

	static VALUE docolon(VALUE sv, VALUE *pv)
	{
	enum { NMATCH = 2 };
	VALUE *v;
	regex_t re_buffer;
	regmatch_t re_regs[NMATCH];

	tostring(sv);
	tostring(pv);

	if (pv->u.s[0] == '^') {
	bb_error_msg(
	"warning: '%s': using '^' as the first character\n"
	"of a basic regular expression is not portable; it is ignored", pv->u.s);
	}

	memset(&re_buffer, 0, sizeof(re_buffer));
	memset(re_regs, 0, sizeof(re_regs));
	xregcomp(&re_buffer, pv->u.s, 0);

	/* expr uses an anchored pattern match, so check that there was a
	* match and that the match starts at offset 0. */
	if (regexec(&re_buffer, sv->u.s, NMATCH, re_regs, 0) != REG_NOMATCH
	&& re_regs[0].rm_so == 0
	) {
	/* Were \(...\) used? */
	if (re_buffer.re_nsub > 0 && re_regs[1].rm_so >= 0) {
	sv->u.s[re_regs[1].rm_eo] = '\0';
	v = str_value(sv->u.s + re_regs[1].rm_so);
	} else {
	v = int_value(re_regs[0].rm_eo);
	}
	} else {
	/* Match failed -- return the right kind of null. */
	if (re_buffer.re_nsub > 0)
	v = str_value("");
	else
	v = int_value(0);
	}
	regfree(&re_buffer);
	return v;
	}

	/* Handle bare operands and ( expr ) syntax. */

	static VALUE *eval7(void)
	{
	VALUE *v;

	if (!*G.args)
	bb_error_msg_and_die("syntax error");

	if (nextarg("(")) {
	G.args++;
	v = eval();
	if (!nextarg(")"))
	bb_error_msg_and_die("syntax error");
	G.args++;
	return v;
	}

	if (nextarg(")"))
	bb_error_msg_and_die("syntax error");

	return str_value(*G.args++);
	}

	/* Handle match, substr, index, length, and quote keywords. */

	static VALUE *eval6(void)
	{
	static const char keywords[] ALIGN1 =
	"quote\0""length\0""match\0""index\0""substr\0";

	VALUE r, i1, *i2;
	VALUE l = l; / silence gcc */
	VALUE v = v; / silence gcc */
	int key = G.args ? index_in_strings(keywords, G.args) + 1 : 0;

	if (key == 0) /* not a keyword */
	return eval7();
	G.args++; /* We have a valid token, so get the next argument. */
	if (key == 1) { /* quote */
	if (!*G.args)
	bb_error_msg_and_die("syntax error");
	return str_value(*G.args++);
	}
	if (key == 2) { /* length */
	r = eval6();
	tostring(r);
	v = int_value(strlen(r->u.s));
	freev(r);
	} else
	l = eval6();

	if (key == 3) { /* match */
	r = eval6();
	v = docolon(l, r);
	freev(l);
	freev(r);
	}
	if (key == 4) { /* index */
	r = eval6();
	tostring(l);
	tostring(r);
	v = int_value(strcspn(l->u.s, r->u.s) + 1);
	if (v->u.i == (arith_t) strlen(l->u.s) + 1)
	v->u.i = 0;
	freev(l);
	freev(r);
	}
	if (key == 5) { /* substr */
	i1 = eval6();
	i2 = eval6();
	tostring(l);
	if (!toarith(i1) \|\| !toarith(i2)
	\|\| i1->u.i > (arith_t) strlen(l->u.s)
	\|\| i1->u.i <= 0 \|\| i2->u.i <= 0)
	v = str_value("");
	else {
	v = xmalloc(sizeof(VALUE));
	v->type = STRING;
	v->u.s = xstrndup(l->u.s + i1->u.i - 1, i2->u.i);
	}
	freev(l);
	freev(i1);
	freev(i2);
	}
	return v;
	}

	/* Handle : operator (pattern matching).
	Calls docolon to do the real work. */

	static VALUE *eval5(void)
	{
	VALUE l, r, *v;

	l = eval6();
	while (nextarg(":")) {
	G.args++;
	r = eval6();
	v = docolon(l, r);
	freev(l);
	freev(r);
	l = v;
	}
	return l;
	}

	/* Handle , /, % operators. /

	static VALUE *eval4(void)
	{
	VALUE l, r;
	int op;
	arith_t val;

	l = eval5();
	while (1) {
	op = nextarg("*");
	if (!op) { op = nextarg("/");
	if (!op) { op = nextarg("%");
	if (!op) return l;
	}}
	G.args++;
	r = eval5();
	val = arithmetic_common(l, r, op);
	freev(l);
	freev(r);
	l = int_value(val);
	}
	}

	/* Handle +, - operators. */

	static VALUE *eval3(void)
	{
	VALUE l, r;
	int op;
	arith_t val;

	l = eval4();
	while (1) {
	op = nextarg("+");
	if (!op) {
	op = nextarg("-");
	if (!op) return l;
	}
	G.args++;
	r = eval4();
	val = arithmetic_common(l, r, op);
	freev(l);
	freev(r);
	l = int_value(val);
	}
	}

	/* Handle comparisons. */

	static VALUE *eval2(void)
	{
	VALUE l, r;
	int op;
	arith_t val;

	l = eval3();
	while (1) {
	op = nextarg("<");
	if (!op) { op = nextarg("<=");
	if (!op) { op = nextarg("=");
	if (!op) { op = nextarg("==");
	if (!op) { op = nextarg("!=");
	if (!op) { op = nextarg(">=");
	if (!op) { op = nextarg(">");
	if (!op) return l;
	}}}}}}
	G.args++;
	r = eval3();
	toarith(l);
	toarith(r);
	val = cmp_common(l, r, op);
	freev(l);
	freev(r);
	l = int_value(val);
	}
	}

	/* Handle &. */

	static VALUE *eval1(void)
	{
	VALUE l, r;

	l = eval2();
	while (nextarg("&")) {
	G.args++;
	r = eval2();
	if (null(l) \|\| null(r)) {
	freev(l);
	freev(r);
	l = int_value(0);
	} else
	freev(r);
	}
	return l;
	}

	/* Handle \|. */

	static VALUE *eval(void)
	{
	VALUE l, r;

	l = eval1();
	while (nextarg("\|")) {
	G.args++;
	r = eval1();
	if (null(l)) {
	freev(l);
	l = r;
	} else
	freev(r);
	}
	return l;
	}

	int expr_main(int argc, char **argv) MAIN_EXTERNALLY_VISIBLE;
	int expr_main(int argc UNUSED_PARAM, char **argv)
	{
	VALUE *v;

	INIT_G();

	xfunc_error_retval = 2; /* coreutils compat */
	G.args = argv + 1;
	if (*G.args == NULL) {
	bb_error_msg_and_die("too few arguments");
	}
	v = eval();
	if (*G.args)
	bb_error_msg_and_die("syntax error");
	if (v->type == INTEGER)
	printf("%" PF_REZ "d\n", PF_REZ_TYPE v->u.i);
	else
	puts(v->u.s);
	fflush_stdout_and_exit(null(v));
	}