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/*
 * netsniff-ng - the packet sniffing beast
 * By Daniel Borkmann <daniel@netsniff-ng.org>
 * Copyright 2012 Daniel Borkmann <dborkma@tik.ee.ethz.ch>,
 * Swiss federal institute of technology (ETH Zurich)
 * Subject to the GPL, version 2.
 */

/* lex-func-prefix: yy */

%{

#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <ctype.h>
#include <stdbool.h>
#include <arpa/inet.h>

#include "trafgen_parser.tab.h"
#include "xmalloc.h"
#include "built_in.h"
#include "str.h"

extern void yyerror(const char *);

static char *try_convert_shellcode(char *sstr)
{
	bool found_any = false;
	char *bstr, *ostr = sstr, *hay, *orig = sstr;
	size_t j = 0, blen, slen = strlen(sstr), tot = 0;
	const char *needle = "\\x";

	sstr++;
	slen -= 2;

	if (slen % 4 != 0)
		return orig;

	blen = slen / 4;
	hay = sstr;
	while ((hay = strstr(hay, needle)) != NULL ) {
		hay += strlen(needle) + 2;
		found_any = true;
		tot++;
	}

	if (blen != tot || !found_any)
		return orig;

	blen += 2;
	bstr = xzmalloc(blen);

	bstr[j++] = '\"';
	while (j < blen - 1)
		bstr[j++] = (uint8_t) strtoul(sstr + 2, &sstr, 16);
	bstr[j++] = '\"';

	xfree(ostr);
	return bstr;
}

%}

%option align
%option nounput
%option noyywrap
%option noreject
%option 8bit
%option caseless
%option noinput
%option nodefault

number_oct	([0][0-9]+)
number_hex	([0]?[x][a-fA-F0-9]+)
number_bin	([0]?[b][0-1]+)
number_dec	(([0])|([1-9][0-9]*))
number_ascii	([a-zA-Z])

a_hex		([a-fA-F0-9]+)
mac		({a_hex}:{a_hex}:{a_hex}:{a_hex}:{a_hex}:{a_hex})
ip4_addr	([0-9]+\.[0-9]+\.[0-9]+\.[0-9]+)
	/* We're very permissive about IPv6 addresses the grammar accepts, as
	 * they can come in various different formats. In any case,
	 * inet_pton(AF_INET6, ...) will reject the invalid ones later on. */
ip6_addr	(({a_hex}?:)?({a_hex}?:)?({a_hex}?:)?({a_hex}?:)?({a_hex}?:)?({a_hex}?:)?({a_hex}?:)?({a_hex})?)

%%

"cpu"		{ return K_CPU; }
"fill"		{ return K_FILL; }
"rnd"		{ return K_RND; }
"csum16"	{ return K_CSUMIP; }
"csumip"	{ return K_CSUMIP; }
"csumip4"	{ return K_CSUMIP; }
"csumicmp"	{ return K_CSUMIP; }
"csumicmp4"	{ return K_CSUMIP; }
"csumudp"	{ return K_CSUMUDP; }
"csumtcp"	{ return K_CSUMTCP; }
"csumudp6"	{ return K_CSUMUDP6; }
"csumtcp6"	{ return K_CSUMTCP6; }
"drnd"		{ return K_DRND; }
"dinc"		{ return K_DINC; }
"ddec"		{ return K_DDEC; }
"seqinc"	{ return K_SEQINC; }
"seqdec"	{ return K_SEQDEC; }
"const8"|"c8"	{ return K_CONST8; }
"const16"|"c16"	{ return K_CONST16; }
"const32"|"c32"	{ return K_CONST32; }
"const64"|"c64"	{ return K_CONST64; }

"prot"[o]?	{ return K_PROT; }
"tc"|"tclass"	{ return K_TC; }

	/* Ethernet */
"daddr"|"da"	{ return K_DADDR; }
"saddr"|"sa"	{ return K_SADDR; }
"etype"	        { return K_ETYPE; }
"type"	        { return K_TYPE; }

	/* IEEE 802.3X PAUSE */
"time"		{ return K_TIME; }

	/* VLAN (802.1Q & 802.1ad) */
"tpid"		{ return K_TPID; }
"tci"		{ return K_TCI; }
"pcp"		{ return K_PCP; }
"dei"|"cfi"	{ return K_DEI; }
"1ad"		{ return K_1AD; }
"1q"		{ return K_1Q; }

	/* MPLS (Multi Protocol Label Switching) */
"lbl"|"label"	{ return K_LABEL; }
"last"		{ return K_LAST; }
"exp"		{ return K_EXP; }

	/* ARP */
"sha"|"smac"	{ return K_SHA; }
"spa"|"sip"	{ return K_SPA; }
"tha"|"tmac"	{ return K_THA; }
"tpa"|"tip"	{ return K_TPA; }
"req"|"request"	{ return K_REQUEST; }
"reply"		{ return K_REPLY; }
"op"|"oper"	{ return K_OPER; }
"htype"		{ return K_HTYPE; }
"ptype"		{ return K_PTYPE; }

	/* IPv4 */
"ihl"		{ return K_IHL; }
"ver"|"version"	{ return K_VER; }
"ttl"		{ return K_TTL; }
"dscp"		{ return K_DSCP; }
"ecn"		{ return K_ECN; }
"tos"		{ return K_TOS; }
"len"|"length"	{ return K_LEN; }
"id"		{ return K_ID; }
"flags"		{ return K_FLAGS; }
"frag"		{ return K_FRAG; }
"csum"		{ return K_CSUM; }
"df"		{ return K_DF; }
"mf"		{ return K_MF; }

	/* IPv6 */
"fl"|"flow"	{ return K_FLOW; }
"nh"|"nexthdr"	{ return K_NEXT_HDR; }
"hl"|"hoplimit"	{ return K_HOP_LIMIT; }


	/* ICMPv4 */
"addr"		{ return K_ADDR; }
"mtu"		{ return K_MTU; }

	/* ICMPv6 */
"code"		{ return K_CODE; }
"echorequest"	{ return K_ECHO_REQUEST; }
"echoreply"	{ return K_ECHO_REPLY; }

	/* UDP */
"sp"|"sport"	{ return K_SPORT; }
"dp"|"dport"	{ return K_DPORT; }

	/* TCP */
"seq"		{ return K_SEQ; }
"ackseq"|"aseq"	{ return K_ACK_SEQ; }
"doff"|hlen	{ return K_DOFF; }
"cwr"		{ return K_CWR; }
"ece"|"ecn"	{ return K_ECE; }
"urg"		{ return K_URG; }
"ack"		{ return K_ACK; }
"psh"		{ return K_PSH; }
"rst"		{ return K_RST; }
"syn"		{ return K_SYN; }
"fin"		{ return K_FIN; }
"win"|"window"	{ return K_WINDOW; }
"urgptr"	{ return K_URG_PTR; }

"eth"		{ return K_ETH; }
"pause"         { return K_PAUSE; }
"vlan"		{ return K_VLAN; }
"mpls"		{ return K_MPLS; }
"arp"		{ return K_ARP; }
"ip4"|"ipv4"	{ return K_IP4; }
"ip6"|"ipv6"	{ return K_IP6; }
"icmp4"|"icmpv4" { return K_ICMP4; }
"icmp6"|"icmpv6"	{ return K_ICMP6; }
"udp"		{ return K_UDP; }
"tcp"		{ return K_TCP; }

[ ]*"-"[ ]*	{ return '-'; }
[ ]*"+"[ ]*	{ return '+'; }
[ ]*"*"[ ]*	{ return '*'; }
[ ]*"/"[ ]*	{ return '/'; }
[ ]*"%"[ ]*	{ return '%'; }
[ ]*"&"[ ]*	{ return '&'; }
[ ]*"|"[ ]*	{ return '|'; }
[ ]*"<"[ ]*	{ return '<'; }
[ ]*">"[ ]*	{ return '>'; }
[ ]*"^"[ ]*	{ return '^'; }
"{"		{ return '{'; }
"}"		{ return '}'; }
"("		{ return '('; }
")"		{ return ')'; }
"["		{ return '['; }
"]"		{ return ']'; }
","		{ return ','; }
":"		{ return ':'; }
"="		{ return '='; }

"\n"		{ yylineno++; }

"\""[^\"]+"\""	{ yylval.str = try_convert_shellcode(xstrdup(yytext));
		  return string; }

([ \t\n]+)?	{ return K_WHITE; }

"/*"([^\*]|\*[^/])*"*/" { return K_COMMENT; }

"#"[^\n]*	{ return K_COMMENT; }

{number_hex}	{ yylval.number = strtoul(yytext + (yytext[0] == 'x' ? 1 : 0),
					  NULL, 16);
		  return number; }

{number_dec}	{ yylval.number = strtol(yytext, NULL, 10);
		  return number; }

{number_oct}	{ yylval.number = strtol(yytext + 1, NULL, 8);
		  return number; }

{number_bin}	{ yylval.number = strtol(yytext + (yytext[0] == 'b' ? 1 : 2),
					 NULL, 2);
		  return number; }

{number_ascii}	{ yylval.number = (uint8_t) (*yytext);
		  return number; }

{mac}	        { if (str2mac(yytext, yylval.bytes, 256))
			panic("Failed to parse MAC address %s\n", yytext);
		  return mac; }

{ip4_addr}	{ if (inet_pton(AF_INET, yytext, &yylval.ip4_addr) != 1)
			panic("Failed to parse IPv4 address %s\n", yytext);
		  return ip4_addr; };

{ip6_addr}	{ if (inet_pton(AF_INET6, yytext, &yylval.ip6_addr) != 1)
			panic("Failed to parse IPv6 address %s\n", yytext);
		  return ip6_addr; };

"'\\x"[a-fA-F0-9]{2}"'" { yylval.number = strtol(yytext + 3, NULL, 16);
		  return number; }

"'"."'"		{ yylval.number = (uint8_t) (*(yytext + 1));
		  return number; }

";"[^\n]*	{/* NOP */}
.		{ printf("Unknown character '%s'", yytext);
		  yyerror("lex Unknown character"); }

%%