----------------------------------------------------- Mirrored from: http://users.cecs.anu.edu.au/~bdm/data/formats.html Date: 2023-02-17 ----------------------------------------------------- ----------------------------------------------------- Description of graph6, sparse6 and digraph6 encodings ----------------------------------------------------- Brendan McKay, brendan.mckay@anu.edu.au Updated Jun 2015, Apr 2022. General principles: All numbers in this description are in decimal unless obviously in binary. Apart from the header, there is one object per line. Apart from the header, end-of-line characters, and the characters ":", ";" and "&" which might start a line, all bytes have a value in the range 63-126 (which are all printable ASCII characters). A file of objects is a text file, so whatever end-of-line convention is locally used is fine; however the C library input routines must show the standard single-LF end of line to programs). Bit vectors: A bit vector x of length k can be represented as follows. Example: 1000101100011100 (1) Pad on the right with 0 to make the length a multiple of 6. Example: 100010110001110000 (2) Split into groups of 6 bits each. Example: 100010 110001 110000 (3) Add 63 to each group, considering them as bigendian binary numbers. Example: 97 112 111 These values are then stored one per byte. So, the number of bytes is ceiling(k/6). Let R(x) denote this representation of x as a string of bytes. Small nonnegative integers: Let n be an integer in the range 0-68719476735 (2^36-1). If 0 <= n <= 62, define N(n) to be the single byte n+63. If 63 <= n <= 258047, define N(n) to be the four bytes 126 R(x), where x is the bigendian 18-bit binary form of n. If 258048 <= n <= 68719476735, define N(n) to be the eight bytes 126 126 R(x), where x is the bigendian 36-bit binary form of n. Examples: N(30) = 93 N(12345) = N(000011 000000 111001) = 126 66 63 120 N(460175067) = N(000000 011011 011011 011011 011011 011011) = 126 126 63 90 90 90 90 90 Description of graph6 format. ---------------------------- Data type: simple undirected graphs of order 0 to 68719476735. Optional Header: >>graph6<< (without end of line!) File name extension: .g6 One graph: Suppose G has n vertices. Write the upper triangle of the adjacency matrix of G as a bit vector x of length n(n-1)/2, using the ordering (0,1),(0,2),(1,2),(0,3),(1,3),(2,3),...,(n-2,n-1). Then the graph is represented as N(n) R(x). Example: Suppose n=5 and G has edges 0-2, 0-4, 1-3 and 3-4. x = 0 10 010 1001 Then N(n) = 68 and R(x) = R(010010 100100) = 81 99. So, the graph is 68 81 99. Description of sparse6 format. ------------------------------ Data type: Undirected graphs of order 0 to 68719476735. Loops and multiple edges are permitted. (However, as of May 2022, the utilities in the nauty package and nauty itself do not support multiple edges and some utilities do not support loops either.) Optional Header: >>sparse6<< (without end of line!) File name extension: .s6 General structure: Each graph occupies one text line. Except for the first character and end-of-line characters, each byte has the form 63+x, where 0 <= x <= 63. The byte encodes the six bits of x. The encoded graph consists of: (1) The character ':'. (This is present to distinguish the code from graph6 format.) (2) The number of vertices. (3) A list of edges. (4) end-of-line Loops and multiple edges are supported, but not directed edges. Number of vertices n: 1, 4, or 8 bytes N(n) as above. This is the same as graph6 format. List of edges: Let k be the number of bits needed to represent n-1 in binary. The remaining bytes encode a sequence b[0] x[0] b[1] x[1] b[2] x[2] ... b[m] x[m] Each b[i] occupies 1 bit, and each x[i] occupies k bits. Pack them together in bigendian order, and pad up to a multiple of 6 as follows: 1. If (n,k) = (2,1), (4,2), (8,3) or (16,4), and vertex n-2 has an edge but n-1 doesn't have an edge, and there are k+1 or more bits to pad, then pad with one 0-bit and enough 1-bits to complete the multiple of 6. 2. Otherwise, pad with enough 1-bits to complete the multiple of 6. These rules are to match the gtools procedures, and to avoid the padding from looking like an extra loop in unusual cases. Then represent this bit-stream 6 bits per byte as indicated above. The vertices of the graph are 0..n-1. The edges encoded by this sequence are determined thus: v = 0 for i from 0 to m do if b[i] = 1 then v = v+1 endif; if x[i] > v then v = x[i] else output {x[i],v} endif endfor In decoding, an incomplete (b,x) pair at the end is discarded. Example: :Fa@x^ ':' indicates sparse6 format. Subtract 63 from the other bytes and write them in binary, six bits each. 000111 100010 000001 111001 011111 The first byte is not 63, so it is n. n=7 n-1 needs 3 bits (k=3). Write the other bits in groups of 1 and k: 1 000 1 000 0 001 1 110 0 101 1 111 This is the b/x sequence 1,0 1,0 0,1 1,6 0,5 1,7. The 1,7 at the end is just padding. The remaining parts give the edges 0-1 0-2 1-2 5-6. Description of incremental sparse6 format. ----------------------------------------- This is an extension to sparse6 format that is very efficient if most graphs in a file are similar to the previous graph. Each graph occupies one text line. Except for the first character and end-of-line characters, each byte has the form 63+x, where 0 <= x <= 63. The byte encodes the six bits of x. The encoded graph consists of: (1) The character ';'. (2) A list of edges. (3) end-of-line This cannot appear as the first graph in a file. The number of vertices is taken to be equal to the number of vertices in the previous graph. The list of edges specifies the symmetric difference of this graph and the previous graph. It is encoded exactly the same as part (3) of sparse6 format. Loops are supported, but not multiple edges. Description of digraph6 format. ------------------------------ Data type: simple directed graphs (allowing loops) of order 0 to 68719476735. Optional Header: >>digraph6<< (without end of line!) File name extension: .d6 One graph: Suppose G has n vertices. Write the adjacency matrix of G as a bit vector x of length n^2, row by row. Then the graph is represented as '&' N(n) R(x). The character '&' (decimal 38) appears as the first character. Example: Suppose n=5 and G has edges 0->2, 0->4, 3->1 and 3->4. x = 00101 00000 00000 01001 00000 Then N(n) = 68 and R(x) = R(00101 00000 00000 01001 00000) = 73 63 65 79 63. So, the graph is 38 68 73 63 65 79 63.