Copyright (C) 2006, Sun Microsystems, Inc. All Rights Reserved
The contents of this file are subject to the terms of the Common Development and Distribution License (the "License"). You may not use this file except in compliance with the License.
You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE or http://www.opensolaris.org/os/licensing. See the License for the specific language governing permissions and limitations under the License.
When distributing Covered Code, include this CDDL HEADER in each file and include the License file at usr/src/OPENSOLARIS.LICENSE. If applicable, add the following below this CDDL HEADER, with the fields enclosed by brackets "[]" replaced with your own identifying information: Portions Copyright [yyyy] [name of copyright owner]
#include <sys/pfmod.h>
ioctl(fd, IPUSH, "pfmod");
pfmod is a STREAMS module that subjects messages arriving on its read queue to a packet filter and passes only those messages that the filter accepts on to its upstream neighbor. Such filtering can be very useful for user-level protocol implementations and for networking monitoring programs that wish to view only specific types of events.
pfmod applies the current packet filter to all M_DATA and M_PROTO messages arriving on its read queue. The module prepares these messages for examination by first skipping over all leading M_PROTO message blocks to arrive at the beginning of the message's data portion. If there is no data portion, pfmod accepts the message and passes it along to its upstream neighbor. Otherwise, the module ensures that the part of the message's data that the packet filter might examine lies in contiguous memory, calling the pullupmsg(9F) utility routine if necessary to force contiguity. (Note: this action destroys any sharing relationships that the subject message might have had with other messages.) Finally, it applies the packet filter to the message's data, passing the entire message upstream to the next module if the filter accepts, and discarding the message otherwise. See PACKET FILTERS below for details on how the filter works.
If there is no packet filter yet in effect, the module acts as if the filter exists but does nothing, implying that all incoming messages are accepted. The ioctls section below describes how to associate a packet filter with an instance of pfmod.
pfmod passes all other messages through unaltered to its upper neighbor.
pfmod intercepts M_IOCTL messages for the ioctl described below. The module passes all other messages through unaltered to its lower neighbor.
pfmod responds to the following ioctl. PFIOCSETF
This ioctl directs the module to replace its current packet filter, if any, with the filter specified by the struct packetfilt pointer named by its final argument. This structure is defined in <sys/pfmod.h> as:
struct packetfilt { uchar_t Pf_Priority; /* priority of filter */ uchar_t Pf_FilterLen; /* length of filter cmd list */ ushort_t Pf_Filter[ENMAXFILTERS]; /* filter command list */ };
The Pf_Priority field is included only for compatibility with other packet filter implementations and is otherwise ignored. The packet filter itself is specified in the Pf_Filter array as a sequence of two-byte commands, with the Pf_FilterLen field giving the number of commands in the sequence. This implementation restricts the maximum number of commands in a filter (ENMAXFILTERS) to 255. The next section describes the available commands and their semantics.
A packet filter consists of the filter command list length (in units of ushort_ts), and the filter command list itself. (The priority field mentioned above is ignored in this implementation.) Each filter command list specifies a sequence of actions that operate on an internal stack of ushort_ts ("shortwords") or an offset register. The offset register is initially zero. Each shortword of the command list specifies an action and a binary operator. Using _n_ as shorthand for the next shortword of the instruction stream and _%oreg_ for the offset register, the list of actions is:
COMMAND SHORTWORDS ACTION ENF_PUSHLIT 2 Push _n_ on the stack. ENF_PUSHZERO 1 Push zero on the stack. ENF_PUSHONE 1 Push one on the stack. ENF_PUSHFFFF 1 Push 0xFFFF on the stack. ENF_PUSHFF00 1 Push 0xFF00 on the stack. ENF_PUSH00FF 1 Push 0x00FF on the stack. ENF_LOAD_OFFSET 2 Load _n_ into _%oreg_. ENF_BRTR 2 Branch forward _n_ shortwords if the top element of the stack is non-zero. ENF_BRFL 2 Branch forward _n_ shortwords if the top element of the stack is zero. ENF_POP 1 Pop the top element from the stack. ENF_PUSHWORD+m 1 Push the value of shortword (_m_ + _%oreg_) of the packet onto the stack.
The binary operators can be from the set {ENF_EQ, ENF_NEQ, ENF_LT, ENF_LE, ENF_GT,ENF_GE, ENF_AND, ENF_OR, ENF_XOR} which operate on the top two elements of the stack and replace them with its result.
When both an action and operator are specified in the same shortword, the action is performed followed by the operation.
The binary operator can also be from the set {ENF_COR, ENF_CAND, ENF_CNOR, ENF_CNAND}. These are "short-circuit" operators, in that they terminate the execution of the filter immediately if the condition they are checking for is found, and continue otherwise. All pop two elements from the stack and compare them for equality; ENF_CAND returns false if the result is false; ENF_COR returns true if the result is true; ENF_CNAND returns true if the result is false; ENF_CNOR returns false if the result is true. Unlike the other binary operators, these four do not leave a result on the stack, even if they continue.
The short-circuit operators should be used when possible, to reduce the amount of time spent evaluating filters. When they are used, you should also arrange the order of the tests so that the filter will succeed or fail as soon as possible; for example, checking the IP destination field of a UDP packet is more likely to indicate failure than the packet type field.
The special action ENF_NOPUSH and the special operator ENF_NOP can be used to only perform the binary operation or to only push a value on the stack. Since both are (conveniently) defined to be zero, indicating only an action actually specifies the action followed by ENF_NOP, and indicating only an operation actually specifies ENF_NOPUSH followed by the operation.
After executing the filter command list, a non-zero value (true) left on top of the stack (or an empty stack) causes the incoming packet to be accepted and a zero value (false) causes the packet to be rejected. (If the filter exits as the result of a short-circuit operator, the top-of-stack value is ignored.) Specifying an undefined operation or action in the command list or performing an illegal operation or action (such as pushing a shortword offset past the end of the packet or executing a binary operator with fewer than two shortwords on the stack) causes a filter to reject the packet.
The packet filter module is not dependent on any particular device driver or module but is commonly used with datalink drivers such as the Ethernet driver. If the underlying datalink driver supports the Data Link Provider Interface (DLPI) message set, the appropriate STREAMS DLPI messages must be issued to attach the stream to a particular hardware device and bind a datalink address to the stream before the underlying driver will route received packets upstream. Refer to the DLPI Version 2 specification for details on this interface.
The reverse ARP daemon program may use code similar to the following fragment to construct a filter that rejects all but RARP packets. That is, it accepts only packets whose Ethernet type field has the value ETHERTYPE_REVARP. The filter works whether a VLAN is configured or not.
struct ether_header eh; /* used only for offset values */ struct packetfilt pf; register ushort_t *fwp = pf.Pf_Filter; ushort_t offset; int fd; /* * Push packet filter streams module. */ if (ioctl(fd, I_PUSH, "pfmod") < 0) syserr("pfmod"); /* * Set up filter. Offset is the displacement of the Ethernet * type field from the beginning of the packet in units of * ushort_ts. */ offset = ((uint_t) &eh.ether_type - (uint_t) &eh.ether_dhost) / sizeof (us_short); *fwp++ = ENF_PUSHWORD + offset; *fwp++ = ENF_PUSHLIT; *fwp++ = htons(ETHERTYPE_VLAN); *fwp++ = ENF_EQ; *fwp++ = ENF_BRFL; *fwp++ = 3; /* If this isn't ethertype VLAN, don't change oreg */ *fwp++ = ENF_LOAD_OFFSET; *fwp++ = 2; /* size of the VLAN tag in words */ *fwp++ = ENF_POP; *fwp++ = ENF_PUSHWORD + offset; *fwp++ = ENF_PUSHLIT; *fwp++ = htons(ETHERTYPE_REVARP); *fwp++ = ENF_EQ; pf.Pf_FilterLen = fwp - &pf.PF_Filter[0];
This filter can be abbreviated by taking advantage of the ability to combine actions and operations:
*fwp++ = ENF_PUSHWORD + offset; *fwp++ = ENF_PUSHLIT | ENF_EQ; *fwp++ = htons(ETHERTYPE_REVARP); *fwp++ = htons(ETHERTYPE_VLAN); *fwp++ = ENF_BRFL | ENF_NOP; *fwp++ = 3; *fwp++ = ENF_LOAD_OFFSET | ENF_NOP; *fwp++ = 2; *fwp++ = ENF_POP | ENF_NOP; *fwp++ = ENF_PUSHWORD + offset; *fwp++ = ENF_PUSHLIT | ENF_EQ; *fwp++ = htons(ETHERTYPE_REVARP);
bufmod(7M), dlpi(7P), pullupmsg(9F)