bin/sh/arithmetic.c

1.4  kre /*	$NetBSD: arithmetic.c,v 1.4 2017/07/24 13:21:14 kre Exp $	*/
1.1  kre
1.1  kre /*-
1.1  kre  * Copyright (c) 1993
1.1  kre  *	The Regents of the University of California.  All rights reserved.
1.1  kre  * Copyright (c) 2007
1.1  kre  *	Herbert Xu <herbert (at) gondor.apana.org.au>.  All rights reserved.
1.1  kre  *
1.1  kre  * This code is derived from software contributed to Berkeley by
1.1  kre  * Kenneth Almquist.
1.1  kre  *
1.1  kre  * Redistribution and use in source and binary forms, with or without
1.1  kre  * modification, are permitted provided that the following conditions
1.1  kre  * are met:
1.1  kre  * 1. Redistributions of source code must retain the above copyright
1.1  kre  *    notice, this list of conditions and the following disclaimer.
1.1  kre  * 2. Redistributions in binary form must reproduce the above copyright
1.1  kre  *    notice, this list of conditions and the following disclaimer in the
1.1  kre  *    documentation and/or other materials provided with the distribution.
1.1  kre  * 3. Neither the name of the University nor the names of its contributors
1.1  kre  *    may be used to endorse or promote products derived from this software
1.1  kre  *    without specific prior written permission.
1.1  kre  *
1.1  kre  * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
1.1  kre  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
1.1  kre  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
1.1  kre  * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
1.1  kre  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
1.1  kre  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
1.1  kre  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
1.1  kre  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
1.1  kre  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
1.1  kre  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
1.1  kre  * SUCH DAMAGE.
1.1  kre  *
1.1  kre  * From FreeBSD, who obtained it from dash, modified both times...
1.1  kre  */
1.1  kre
1.1  kre #include <sys/cdefs.h>
1.1  kre
1.1  kre #ifndef lint
1.4  kre __RCSID("$NetBSD: arithmetic.c,v 1.4 2017/07/24 13:21:14 kre Exp $");
1.1  kre #endif /* not lint */
1.1  kre
1.1  kre #include <limits.h>
1.1  kre #include <errno.h>
1.1  kre #include <inttypes.h>
1.1  kre #include <stdlib.h>
1.1  kre #include <stdio.h>
1.3  kre #include <string.h>
1.1  kre
1.1  kre #include "shell.h"
1.1  kre #include "arithmetic.h"
1.1  kre #include "arith_tokens.h"
1.1  kre #include "expand.h"
1.1  kre #include "error.h"
1.1  kre #include "memalloc.h"
1.1  kre #include "output.h"
1.1  kre #include "options.h"
1.1  kre #include "var.h"
1.2  kre #include "show.h"
1.1  kre
1.1  kre #if ARITH_BOR + ARITH_ASS_GAP != ARITH_BORASS || \
1.1  kre 	ARITH_ASS + ARITH_ASS_GAP != ARITH_EQ
1.1  kre #error Arithmetic tokens are out of order.
1.1  kre #endif
1.1  kre
1.1  kre static const char *arith_startbuf;
1.1  kre
1.1  kre const char *arith_buf;
1.1  kre union a_token_val a_t_val;
1.1  kre
1.1  kre static int last_token;
1.1  kre
1.3  kre int arith_lno, arith_var_lno;
1.3  kre
1.1  kre #define ARITH_PRECEDENCE(op, prec) [op - ARITH_BINOP_MIN] = prec
1.1  kre
1.1  kre static const char prec[ARITH_BINOP_MAX - ARITH_BINOP_MIN] = {
1.1  kre 	ARITH_PRECEDENCE(ARITH_MUL, 0),
1.1  kre 	ARITH_PRECEDENCE(ARITH_DIV, 0),
1.1  kre 	ARITH_PRECEDENCE(ARITH_REM, 0),
1.1  kre 	ARITH_PRECEDENCE(ARITH_ADD, 1),
1.1  kre 	ARITH_PRECEDENCE(ARITH_SUB, 1),
1.1  kre 	ARITH_PRECEDENCE(ARITH_LSHIFT, 2),
1.1  kre 	ARITH_PRECEDENCE(ARITH_RSHIFT, 2),
1.1  kre 	ARITH_PRECEDENCE(ARITH_LT, 3),
1.1  kre 	ARITH_PRECEDENCE(ARITH_LE, 3),
1.1  kre 	ARITH_PRECEDENCE(ARITH_GT, 3),
1.1  kre 	ARITH_PRECEDENCE(ARITH_GE, 3),
1.1  kre 	ARITH_PRECEDENCE(ARITH_EQ, 4),
1.1  kre 	ARITH_PRECEDENCE(ARITH_NE, 4),
1.1  kre 	ARITH_PRECEDENCE(ARITH_BAND, 5),
1.1  kre 	ARITH_PRECEDENCE(ARITH_BXOR, 6),
1.1  kre 	ARITH_PRECEDENCE(ARITH_BOR, 7),
1.1  kre };
1.1  kre
1.1  kre #define ARITH_MAX_PREC 8
1.1  kre
1.1  kre int expcmd(int, char **);
1.1  kre
1.1  kre static void __dead
1.1  kre arith_err(const char *s)
1.1  kre {
1.1  kre 	error("arithmetic expression: %s: \"%s\"", s, arith_startbuf);
1.1  kre 	/* NOTREACHED */
1.1  kre }
1.1  kre
1.1  kre static intmax_t
1.1  kre arith_lookupvarint(char *varname)
1.1  kre {
1.1  kre 	const char *str;
1.1  kre 	char *p;
1.1  kre 	intmax_t result;
1.3  kre 	const int oln = line_number;
1.3  kre
1.3  kre 	VTRACE(DBG_ARITH, ("Arith var lookup(\"%s\") with lno=%d\n", varname,
1.3  kre 	    arith_var_lno));
1.1  kre
1.3  kre 	line_number = arith_var_lno;
1.1  kre 	str = lookupvar(varname);
1.3  kre 	line_number = oln;
1.3  kre
1.1  kre 	if (uflag && str == NULL)
1.1  kre 		arith_err("variable not set");
1.1  kre 	if (str == NULL || *str == '\0')
1.1  kre 		str = "0";
1.1  kre 	errno = 0;
1.1  kre 	result = strtoimax(str, &p, 0);
1.1  kre 	if (errno != 0 || *p != '\0')
1.1  kre 		arith_err("variable contains non-numeric value");
1.1  kre 	return result;
1.1  kre }
1.1  kre
1.1  kre static inline int
1.1  kre arith_prec(int op)
1.1  kre {
1.1  kre
1.1  kre 	return prec[op - ARITH_BINOP_MIN];
1.1  kre }
1.1  kre
1.1  kre static inline int
1.1  kre higher_prec(int op1, int op2)
1.1  kre {
1.1  kre
1.1  kre 	return arith_prec(op1) < arith_prec(op2);
1.1  kre }
1.1  kre
1.1  kre static intmax_t
1.1  kre do_binop(int op, intmax_t a, intmax_t b)
1.1  kre {
1.1  kre
1.2  kre 	VTRACE(DBG_ARITH, ("Arith do binop %d (%jd, %jd)\n", op, a, b));
1.1  kre 	switch (op) {
1.1  kre 	default:
1.1  kre 		arith_err("token error");
1.1  kre 	case ARITH_REM:
1.1  kre 	case ARITH_DIV:
1.1  kre 		if (b == 0)
1.1  kre 			arith_err("division by zero");
1.1  kre 		if (a == INTMAX_MIN && b == -1)
1.1  kre 			arith_err("divide error");
1.1  kre 		return op == ARITH_REM ? a % b : a / b;
1.1  kre 	case ARITH_MUL:
1.1  kre 		return (uintmax_t)a * (uintmax_t)b;
1.1  kre 	case ARITH_ADD:
1.1  kre 		return (uintmax_t)a + (uintmax_t)b;
1.1  kre 	case ARITH_SUB:
1.1  kre 		return (uintmax_t)a - (uintmax_t)b;
1.1  kre 	case ARITH_LSHIFT:
1.1  kre 		return (uintmax_t)a << (b & (sizeof(uintmax_t) * CHAR_BIT - 1));
1.1  kre 	case ARITH_RSHIFT:
1.1  kre 		return a >> (b & (sizeof(uintmax_t) * CHAR_BIT - 1));
1.1  kre 	case ARITH_LT:
1.1  kre 		return a < b;
1.1  kre 	case ARITH_LE:
1.1  kre 		return a <= b;
1.1  kre 	case ARITH_GT:
1.1  kre 		return a > b;
1.1  kre 	case ARITH_GE:
1.1  kre 		return a >= b;
1.1  kre 	case ARITH_EQ:
1.1  kre 		return a == b;
1.1  kre 	case ARITH_NE:
1.1  kre 		return a != b;
1.1  kre 	case ARITH_BAND:
1.1  kre 		return a & b;
1.1  kre 	case ARITH_BXOR:
1.1  kre 		return a ^ b;
1.1  kre 	case ARITH_BOR:
1.1  kre 		return a | b;
1.1  kre 	}
1.1  kre }
1.1  kre
1.4  kre static intmax_t assignment(int, int);
1.4  kre static intmax_t comma_list(int, int);
1.1  kre
1.1  kre static intmax_t
1.1  kre primary(int token, union a_token_val *val, int op, int noeval)
1.1  kre {
1.1  kre 	intmax_t result;
1.4  kre 	char sresult[DIGITS(result) + 1];
1.1  kre
1.2  kre 	VTRACE(DBG_ARITH, ("Arith primary: token %d op %d%s\n",
1.2  kre 	    token, op, noeval ? " noeval" : ""));
1.2  kre
1.1  kre 	switch (token) {
1.1  kre 	case ARITH_LPAREN:
1.4  kre 		result = comma_list(op, noeval);
1.1  kre 		if (last_token != ARITH_RPAREN)
1.1  kre 			arith_err("expecting ')'");
1.1  kre 		last_token = arith_token();
1.1  kre 		return result;
1.1  kre 	case ARITH_NUM:
1.1  kre 		last_token = op;
1.1  kre 		return val->val;
1.1  kre 	case ARITH_VAR:
1.4  kre 		result = noeval ? val->val : arith_lookupvarint(val->name);
1.4  kre 		if (op == ARITH_INCR || op == ARITH_DECR) {
1.4  kre 			last_token = arith_token();
1.4  kre 			if (noeval)
1.4  kre 				return val->val;
1.4  kre
1.4  kre 			snprintf(sresult, sizeof(sresult), ARITH_FORMAT_STR,
1.4  kre 			    result + (op == ARITH_INCR ? 1 : -1));
1.4  kre 			setvar(val->name, sresult, 0);
1.4  kre 		} else
1.4  kre 			last_token = op;
1.4  kre 		return result;
1.1  kre 	case ARITH_ADD:
1.1  kre 		*val = a_t_val;
1.1  kre 		return primary(op, val, arith_token(), noeval);
1.1  kre 	case ARITH_SUB:
1.1  kre 		*val = a_t_val;
1.1  kre 		return -primary(op, val, arith_token(), noeval);
1.1  kre 	case ARITH_NOT:
1.1  kre 		*val = a_t_val;
1.1  kre 		return !primary(op, val, arith_token(), noeval);
1.1  kre 	case ARITH_BNOT:
1.1  kre 		*val = a_t_val;
1.1  kre 		return ~primary(op, val, arith_token(), noeval);
1.4  kre 	case ARITH_INCR:
1.4  kre 	case ARITH_DECR:
1.4  kre 		if (op != ARITH_VAR)
1.4  kre 			arith_err("incr/decr require var name");
1.4  kre 		last_token = arith_token();
1.4  kre 		if (noeval)
1.4  kre 			return val->val;
1.4  kre 		result = arith_lookupvarint(a_t_val.name);
1.4  kre 		snprintf(sresult, sizeof(sresult), ARITH_FORMAT_STR,
1.4  kre 			    result += (token == ARITH_INCR ? 1 : -1));
1.4  kre 		setvar(a_t_val.name, sresult, 0);
1.4  kre 		return result;
1.1  kre 	default:
1.1  kre 		arith_err("expecting primary");
1.1  kre 	}
1.1  kre 	return 0;	/* never reached */
1.1  kre }
1.1  kre
1.1  kre static intmax_t
1.1  kre binop2(intmax_t a, int op, int precedence, int noeval)
1.1  kre {
1.1  kre 	union a_token_val val;
1.1  kre 	intmax_t b;
1.1  kre 	int op2;
1.1  kre 	int token;
1.1  kre
1.2  kre 	VTRACE(DBG_ARITH, ("Arith: binop2 %jd op %d (P:%d)%s\n",
1.2  kre 	    a, op, precedence, noeval ? " noeval" : ""));
1.2  kre
1.1  kre 	for (;;) {
1.1  kre 		token = arith_token();
1.1  kre 		val = a_t_val;
1.1  kre
1.1  kre 		b = primary(token, &val, arith_token(), noeval);
1.1  kre
1.1  kre 		op2 = last_token;
1.1  kre 		if (op2 >= ARITH_BINOP_MIN && op2 < ARITH_BINOP_MAX &&
1.1  kre 		    higher_prec(op2, op)) {
1.1  kre 			b = binop2(b, op2, arith_prec(op), noeval);
1.1  kre 			op2 = last_token;
1.1  kre 		}
1.1  kre
1.1  kre 		a = noeval ? b : do_binop(op, a, b);
1.1  kre
1.1  kre 		if (op2 < ARITH_BINOP_MIN || op2 >= ARITH_BINOP_MAX ||
1.1  kre 		    arith_prec(op2) >= precedence)
1.1  kre 			return a;
1.1  kre
1.1  kre 		op = op2;
1.1  kre 	}
1.1  kre }
1.1  kre
1.1  kre static intmax_t
1.1  kre binop(int token, union a_token_val *val, int op, int noeval)
1.1  kre {
1.1  kre 	intmax_t a = primary(token, val, op, noeval);
1.1  kre
1.1  kre 	op = last_token;
1.1  kre 	if (op < ARITH_BINOP_MIN || op >= ARITH_BINOP_MAX)
1.1  kre 		return a;
1.1  kre
1.1  kre 	return binop2(a, op, ARITH_MAX_PREC, noeval);
1.1  kre }
1.1  kre
1.1  kre static intmax_t
1.1  kre and(int token, union a_token_val *val, int op, int noeval)
1.1  kre {
1.1  kre 	intmax_t a = binop(token, val, op, noeval);
1.1  kre 	intmax_t b;
1.1  kre
1.1  kre 	op = last_token;
1.1  kre 	if (op != ARITH_AND)
1.1  kre 		return a;
1.1  kre
1.2  kre 	VTRACE(DBG_ARITH, ("Arith: AND %jd%s\n", a, noeval ? " noeval" : ""));
1.2  kre
1.1  kre 	token = arith_token();
1.1  kre 	*val = a_t_val;
1.1  kre
1.1  kre 	b = and(token, val, arith_token(), noeval | !a);
1.1  kre
1.1  kre 	return a && b;
1.1  kre }
1.1  kre
1.1  kre static intmax_t
1.1  kre or(int token, union a_token_val *val, int op, int noeval)
1.1  kre {
1.1  kre 	intmax_t a = and(token, val, op, noeval);
1.1  kre 	intmax_t b;
1.1  kre
1.1  kre 	op = last_token;
1.1  kre 	if (op != ARITH_OR)
1.1  kre 		return a;
1.1  kre
1.2  kre 	VTRACE(DBG_ARITH, ("Arith: OR %jd%s\n", a, noeval ? " noeval" : ""));
1.2  kre
1.1  kre 	token = arith_token();
1.1  kre 	*val = a_t_val;
1.1  kre
1.1  kre 	b = or(token, val, arith_token(), noeval | !!a);
1.1  kre
1.1  kre 	return a || b;
1.1  kre }
1.1  kre
1.1  kre static intmax_t
1.1  kre cond(int token, union a_token_val *val, int op, int noeval)
1.1  kre {
1.1  kre 	intmax_t a = or(token, val, op, noeval);
1.1  kre 	intmax_t b;
1.1  kre 	intmax_t c;
1.1  kre
1.1  kre 	if (last_token != ARITH_QMARK)
1.1  kre 		return a;
1.1  kre
1.2  kre 	VTRACE(DBG_ARITH, ("Arith: ?: %jd%s\n", a, noeval ? " noeval" : ""));
1.2  kre
1.1  kre 	b = assignment(arith_token(), noeval | !a);
1.1  kre
1.1  kre 	if (last_token != ARITH_COLON)
1.1  kre 		arith_err("expecting ':'");
1.1  kre
1.1  kre 	token = arith_token();
1.1  kre 	*val = a_t_val;
1.1  kre
1.1  kre 	c = cond(token, val, arith_token(), noeval | !!a);
1.1  kre
1.1  kre 	return a ? b : c;
1.1  kre }
1.1  kre
1.1  kre static intmax_t
1.1  kre assignment(int var, int noeval)
1.1  kre {
1.1  kre 	union a_token_val val = a_t_val;
1.1  kre 	int op = arith_token();
1.1  kre 	intmax_t result;
1.1  kre 	char sresult[DIGITS(result) + 1];
1.1  kre
1.1  kre
1.1  kre 	if (var != ARITH_VAR)
1.1  kre 		return cond(var, &val, op, noeval);
1.1  kre
1.1  kre 	if (op != ARITH_ASS && (op < ARITH_ASS_MIN || op >= ARITH_ASS_MAX))
1.1  kre 		return cond(var, &val, op, noeval);
1.1  kre
1.2  kre 	VTRACE(DBG_ARITH, ("Arith: %s ASSIGN %d%s\n", val.name, op,
1.2  kre 	    noeval ? " noeval" : ""));
1.2  kre
1.1  kre 	result = assignment(arith_token(), noeval);
1.1  kre 	if (noeval)
1.1  kre 		return result;
1.1  kre
1.1  kre 	if (op != ARITH_ASS)
1.1  kre 		result = do_binop(op - ARITH_ASS_GAP,
1.1  kre 		    arith_lookupvarint(val.name), result);
1.1  kre 	snprintf(sresult, sizeof(sresult), ARITH_FORMAT_STR, result);
1.1  kre 	setvar(val.name, sresult, 0);
1.1  kre 	return result;
1.1  kre }
1.1  kre
1.4  kre static intmax_t
1.4  kre comma_list(int token, int noeval)
1.4  kre {
1.4  kre 	intmax_t result = assignment(token, noeval);
1.4  kre
1.4  kre 	while (last_token == ARITH_COMMA) {
1.4  kre 		VTRACE(DBG_ARITH, ("Arith: comma discarding %jd%s\n", result,
1.4  kre 		    noeval ? " noeval" : ""));
1.4  kre 		result = assignment(arith_token(), noeval);
1.4  kre 	}
1.4  kre
1.4  kre 	return result;
1.4  kre }
1.4  kre
1.1  kre intmax_t
1.3  kre arith(const char *s, int lno)
1.1  kre {
1.1  kre 	struct stackmark smark;
1.1  kre 	intmax_t result;
1.3  kre 	const char *p;
1.3  kre 	int nls = 0;
1.1  kre
1.1  kre 	setstackmark(&smark);
1.1  kre
1.3  kre 	arith_lno = lno;
1.3  kre
1.3  kre 	CTRACE(DBG_ARITH, ("Arith(\"%s\", %d) @%d\n", s, lno, arith_lno));
1.3  kre
1.3  kre 	/* check if it is possible we might reference LINENO */
1.3  kre 	p = s;
1.3  kre 	while ((p = strchr(p, 'L')) != NULL) {
1.3  kre 		if (p[1] == 'I' && p[2] == 'N') {
1.3  kre 			/* if it is possible, we need to correct airth_lno */
1.3  kre 			p = s;
1.3  kre 			while ((p = strchr(p, '\n')) != NULL)
1.3  kre 				nls++, p++;
1.3  kre 			VTRACE(DBG_ARITH, ("Arith found %d newlines\n", nls));
1.3  kre 			arith_lno -= nls;
1.3  kre 			break;
1.3  kre 		}
1.3  kre 		p++;
1.3  kre 	}
1.2  kre
1.1  kre 	arith_buf = arith_startbuf = s;
1.1  kre
1.4  kre 	result = comma_list(arith_token(), 0);
1.1  kre
1.1  kre 	if (last_token)
1.1  kre 		arith_err("expecting end of expression");
1.1  kre
1.1  kre 	popstackmark(&smark);
1.1  kre
1.2  kre 	CTRACE(DBG_ARITH, ("Arith result=%jd\n", result));
1.2  kre
1.1  kre 	return result;
1.1  kre }
1.1  kre
1.1  kre /*
1.1  kre  *  The let(1)/exp(1) builtin.
1.1  kre  */
1.1  kre int
1.1  kre expcmd(int argc, char **argv)
1.1  kre {
1.1  kre 	const char *p;
1.1  kre 	char *concat;
1.1  kre 	char **ap;
1.1  kre 	intmax_t i;
1.1  kre
1.1  kre 	if (argc > 1) {
1.1  kre 		p = argv[1];
1.1  kre 		if (argc > 2) {
1.1  kre 			/*
1.1  kre 			 * Concatenate arguments.
1.1  kre 			 */
1.1  kre 			STARTSTACKSTR(concat);
1.1  kre 			ap = argv + 2;
1.1  kre 			for (;;) {
1.1  kre 				while (*p)
1.1  kre 					STPUTC(*p++, concat);
1.1  kre 				if ((p = *ap++) == NULL)
1.1  kre 					break;
1.1  kre 				STPUTC(' ', concat);
1.1  kre 			}
1.1  kre 			STPUTC('\0', concat);
1.1  kre 			p = grabstackstr(concat);
1.1  kre 		}
1.1  kre 	} else
1.1  kre 		p = "";
1.1  kre
1.3  kre 	i = arith(p, line_number);
1.1  kre
1.1  kre 	out1fmt(ARITH_FORMAT_STR "\n", i);
1.1  kre 	return !i;
1.1  kre }