1 U32 tests whether quantities of up to 4 bytes extracted from a packet have 2 specified values. The specification of what to extract is general enough to 3 find data at given offsets from tcp headers or payloads. 4 .TP 5 [\fB!\fP] \fB\-\-u32\fP \fItests\fP 6 The argument amounts to a program in a small language described below. 7 .IP 8 tests := location "=" value | tests "&&" location "=" value 9 .IP 10 value := range | value "," range 11 .IP 12 range := number | number ":" number 13 .PP 14 a single number, \fIn\fP, is interpreted the same as \fIn:n\fP. \fIn:m\fP is 15 interpreted as the range of numbers \fB>=n\fP and \fB<=m\fP. 16 .IP "" 4 17 location := number | location operator number 18 .IP "" 4 19 operator := "&" | "<<" | ">>" | "@" 20 .PP 21 The operators \fB&\fP, \fB<<\fP, \fB>>\fP and \fB&&\fP mean the same as in C. 22 The \fB=\fP is really a set membership operator and the value syntax describes 23 a set. The \fB@\fP operator is what allows moving to the next header and is 24 described further below. 25 .PP 26 There are currently some artificial implementation limits on the size of the 27 tests: 28 .IP " *" 29 no more than 10 of "\fB=\fP" (and 9 "\fB&&\fP"s) in the u32 argument 30 .IP " *" 31 no more than 10 ranges (and 9 commas) per value 32 .IP " *" 33 no more than 10 numbers (and 9 operators) per location 34 .PP 35 To describe the meaning of location, imagine the following machine that 36 interprets it. There are three registers: 37 .IP 38 A is of type \fBchar *\fP, initially the address of the IP header 39 .IP 40 B and C are unsigned 32 bit integers, initially zero 41 .PP 42 The instructions are: 43 .IP 44 number B = number; 45 .IP 46 C = (*(A+B)<<24) + (*(A+B+1)<<16) + (*(A+B+2)<<8) + *(A+B+3) 47 .IP 48 &number C = C & number 49 .IP 50 << number C = C << number 51 .IP 52 >> number C = C >> number 53 .IP 54 @number A = A + C; then do the instruction number 55 .PP 56 Any access of memory outside [skb\->data,skb\->end] causes the match to fail. 57 Otherwise the result of the computation is the final value of C. 58 .PP 59 Whitespace is allowed but not required in the tests. However, the characters 60 that do occur there are likely to require shell quoting, so it is a good idea 61 to enclose the arguments in quotes. 62 .PP 63 Example: 64 .IP 65 match IP packets with total length >= 256 66 .IP 67 The IP header contains a total length field in bytes 2-3. 68 .IP 69 \-\-u32 "\fB0 & 0xFFFF = 0x100:0xFFFF\fP" 70 .IP 71 read bytes 0-3 72 .IP 73 AND that with 0xFFFF (giving bytes 2-3), and test whether that is in the range 74 [0x100:0xFFFF] 75 .PP 76 Example: (more realistic, hence more complicated) 77 .IP 78 match ICMP packets with icmp type 0 79 .IP 80 First test that it is an ICMP packet, true iff byte 9 (protocol) = 1 81 .IP 82 \-\-u32 "\fB6 & 0xFF = 1 &&\fP ... 83 .IP 84 read bytes 6-9, use \fB&\fP to throw away bytes 6-8 and compare the result to 85 1. Next test that it is not a fragment. (If so, it might be part of such a 86 packet but we cannot always tell.) N.B.: This test is generally needed if you 87 want to match anything beyond the IP header. The last 6 bits of byte 6 and all 88 of byte 7 are 0 iff this is a complete packet (not a fragment). Alternatively, 89 you can allow first fragments by only testing the last 5 bits of byte 6. 90 .IP 91 ... \fB4 & 0x3FFF = 0 &&\fP ... 92 .IP 93 Last test: the first byte past the IP header (the type) is 0. This is where we 94 have to use the @syntax. The length of the IP header (IHL) in 32 bit words is 95 stored in the right half of byte 0 of the IP header itself. 96 .IP 97 ... \fB0 >> 22 & 0x3C @ 0 >> 24 = 0\fP" 98 .IP 99 The first 0 means read bytes 0-3, \fB>>22\fP means shift that 22 bits to the 100 right. Shifting 24 bits would give the first byte, so only 22 bits is four 101 times that plus a few more bits. \fB&3C\fP then eliminates the two extra bits 102 on the right and the first four bits of the first byte. For instance, if IHL=5, 103 then the IP header is 20 (4 x 5) bytes long. In this case, bytes 0-1 are (in 104 binary) xxxx0101 yyzzzzzz, \fB>>22\fP gives the 10 bit value xxxx0101yy and 105 \fB&3C\fP gives 010100. \fB@\fP means to use this number as a new offset into 106 the packet, and read four bytes starting from there. This is the first 4 bytes 107 of the ICMP payload, of which byte 0 is the ICMP type. Therefore, we simply 108 shift the value 24 to the right to throw out all but the first byte and compare 109 the result with 0. 110 .PP 111 Example: 112 .IP 113 TCP payload bytes 8-12 is any of 1, 2, 5 or 8 114 .IP 115 First we test that the packet is a tcp packet (similar to ICMP). 116 .IP 117 \-\-u32 "\fB6 & 0xFF = 6 &&\fP ... 118 .IP 119 Next, test that it is not a fragment (same as above). 120 .IP 121 ... \fB0 >> 22 & 0x3C @ 12 >> 26 & 0x3C @ 8 = 1,2,5,8\fP" 122 .IP 123 \fB0>>22&3C\fP as above computes the number of bytes in the IP header. \fB@\fP 124 makes this the new offset into the packet, which is the start of the TCP 125 header. The length of the TCP header (again in 32 bit words) is the left half 126 of byte 12 of the TCP header. The \fB12>>26&3C\fP computes this length in bytes 127 (similar to the IP header before). "@" makes this the new offset, which is the 128 start of the TCP payload. Finally, 8 reads bytes 8-12 of the payload and 129 \fB=\fP checks whether the result is any of 1, 2, 5 or 8. 130
