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diff --git a/source-builder/sb/asciidoc/examples/website/asciidoc-graphviz-sample.txt b/source-builder/sb/asciidoc/examples/website/asciidoc-graphviz-sample.txt deleted file mode 100644 index 4be6ba9..0000000 --- a/source-builder/sb/asciidoc/examples/website/asciidoc-graphviz-sample.txt +++ /dev/null @@ -1,170 +0,0 @@ -= Graphviz filter for AsciiDoc = - -Author: Gouichi Iisaka - -Version: 1.1.3 - -== Introduction == - -The Graphviz(link:http://www.graphviz.org[]) is a way of representing structural information -as diagrams of abstract graphs and networks. - - -Automatic graph drawing has many important applications -in software engineering, database and web design, networking, -and in visual interfaces for many other domains. - -Graphviz take descriptions of graphs in a simple text language, -And has many useful features for concrete diagrams, -such as options for colors, fonts, tabular node layouts, -line styles, hyperlinks, and custom shapes. - -AsciiDoc can external shell commands used to process Paragraph and -DelimitedBlock content by Filter. - -So now, AsciiDoc can draw graphs via graphviz filter. - -== Examples == - -=== Simple === -..................................................................... -[graphviz] ---------------------------------------------------------------------- -digraph G { rankdir=LR; Graphviz->AsciiDoc->HTML} ---------------------------------------------------------------------- -..................................................................... - -[graphviz] ---------------------------------------------------------------------- -digraph G { rankdir=LR; Graphviz->AsciiDoc->HTML} ---------------------------------------------------------------------- - -=== Using options === -..................................................................... -["graphviz", "sample2.png"] ---------------------------------------------------------------------- -digraph automata_0 { - size ="8.5, 11"; - node [shape = circle]; - 0 [ style = filled, color=lightgrey ]; - 2 [ shape = doublecircle ]; - 0 -> 2 [ label = "a " ]; - 0 -> 1 [ label = "other " ]; - 1 -> 2 [ label = "a " ]; - 1 -> 1 [ label = "other " ]; - 2 -> 2 [ label = "a " ]; - 2 -> 1 [ label = "other " ]; - "Machine: a" [ shape = plaintext ]; -} ---------------------------------------------------------------------- -..................................................................... - -["graphviz", "sample2.png"] ---------------------------------------------------------------------- -digraph automata_0 { - size ="8.5, 11"; - node [shape = circle]; - 0 [ style = filled, color=lightgrey ]; - 2 [ shape = doublecircle ]; - 0 -> 2 [ label = "a " ]; - 0 -> 1 [ label = "other " ]; - 1 -> 2 [ label = "a " ]; - 1 -> 1 [ label = "other " ]; - 2 -> 2 [ label = "a " ]; - 2 -> 1 [ label = "other " ]; - "Machine: a" [ shape = plaintext ]; -} ---------------------------------------------------------------------- - -=== Using Layout === - -..................................................................... -["graphviz", "sample3.png", "dot"] ---------------------------------------------------------------------- -digraph finite_state_machine { - rankdir=LR; - size="8,5" - node [shape = doublecircle]; LR_0 LR_3 LR_4 LR_8; - node [shape = circle]; - LR_0 -> LR_2 [ label = "SS(B)" ]; - LR_0 -> LR_1 [ label = "SS(S)" ]; - LR_1 -> LR_3 [ label = "S($end)" ]; - LR_2 -> LR_6 [ label = "SS(b)" ]; - LR_2 -> LR_5 [ label = "SS(a)" ]; - LR_2 -> LR_4 [ label = "S(A)" ]; - LR_5 -> LR_7 [ label = "S(b)" ]; - LR_5 -> LR_5 [ label = "S(a)" ]; - LR_6 -> LR_6 [ label = "S(b)" ]; - LR_6 -> LR_5 [ label = "S(a)" ]; - LR_7 -> LR_8 [ label = "S(b)" ]; - LR_7 -> LR_5 [ label = "S(a)" ]; - LR_8 -> LR_6 [ label = "S(b)" ]; - LR_8 -> LR_5 [ label = "S(a)" ]; -} ---------------------------------------------------------------------- -..................................................................... - -["graphviz", "sample3.png", "dot"] ---------------------------------------------------------------------- -digraph finite_state_machine { - rankdir=LR; - size="8,5" - node [shape = doublecircle]; LR_0 LR_3 LR_4 LR_8; - node [shape = circle]; - LR_0 -> LR_2 [ label = "SS(B)" ]; - LR_0 -> LR_1 [ label = "SS(S)" ]; - LR_1 -> LR_3 [ label = "S($end)" ]; - LR_2 -> LR_6 [ label = "SS(b)" ]; - LR_2 -> LR_5 [ label = "SS(a)" ]; - LR_2 -> LR_4 [ label = "S(A)" ]; - LR_5 -> LR_7 [ label = "S(b)" ]; - LR_5 -> LR_5 [ label = "S(a)" ]; - LR_6 -> LR_6 [ label = "S(b)" ]; - LR_6 -> LR_5 [ label = "S(a)" ]; - LR_7 -> LR_8 [ label = "S(b)" ]; - LR_7 -> LR_5 [ label = "S(a)" ]; - LR_8 -> LR_6 [ label = "S(b)" ]; - LR_8 -> LR_5 [ label = "S(a)" ]; - } ---------------------------------------------------------------------- - - -== Layout == - -Layout for graphviz as follows. The default is `dot'. - - *dot;; - 'dot' draws directed graphs. - It works well on DAGs and other graphs that can be drawn as hierarchies. - It reads attributed graph files and writes drawings. - - *neato;; - 'neato' draws undirected graphs using ‘‘spring'' models (see Kamada and - Kawai, Information Processing Letters 31:1, April 1989). - Input files must be formatted in the dot attributed graph language. - - *twopi;; - 'twopi' draws graphs using a radial layout (see G. Wills, Symposium on - Graph Drawing GD'97, September, 1997). - Basically, one node is chosen as the center and put at the origin. - The remaining nodes are placed on a sequence of concentric circles - centered about the origin, each a fixed radial distance from - the previous circle. - - *circro;; - 'circo' draws graphs using a circular layout (see Six and Tollis, GD '99 - and ALENEX '99, and Kaufmann and Wiese, GD '02.) - The tool identifies biconnected components and draws the nodes - of the component on a circle. - The block‐cutpoint tree is then laid out using a recursive radial - algorithm. - Edge crossings within a circle are minimized by placing as - many edges on the circle's perimeter as possible. - In particular, if the component is outerplanar, - the component will have a planar layout. - - *fdp;; - 'fdp' draws undirected graphs using a ‘‘spring'' model. - It relies on a force‐directed approach in the spirit of Fruchterman - and Reingold - (cf. Software‐Practice & Experience 21(11), 1991, pp. 1129‐1164). |