package bap-std
Control Flow Graph with a machine basic block as a node.
A graph is a set of relations between objects, defined as a pair of two sets
G = (V,E).
where $V$ is a set of vertices and E is a set of vertices, which is a subset of V x V, therefore a more precise definition is a 6-tuple, consisting of a set of nodes, edges, node labels, edge labels, and two functions that maps nodes and edges to their corresponding labels:
G = (N, E, N', E', ν : N -> N', ε : E -> E'),
where set E is a subset of N × N .
With this general framework an unlabeled graph can be represented as:
G = (N, E, N, E, ν = λx.x, ε = λx.x)
Another possible representation of an unlabeled graph would be:
G = (N, E, {u}, {v}, ν = λx.u, ε = λx.v).Implementations are free to choose any suitable representation of graph data structure, if it conforms to the graph signature and all operations follows the described semantics and properties of a graph structure are preserved.
The axiomatic semantics of operations on a graph is described by a set of postconditions. To describe the semantics of an operation in terms of input and output arguments, we project graphs to its fields with the following notation <field>(<graph>), e.g., N(g) is a set of nodes of graph g.
type t = cfgtype of graph
type node = blocktype of nodes
Graph nodes.
module Edge :
Graphlib.Std.Edge
with type graph = t
and type t = edge
and type node = node
with type label = edgeGraph edges
val empty : tempty is an empty graph
val nodes : t -> node Regular.Std.seqnodes g returns all nodes of graph g in an unspecified order
val edges : t -> edge Regular.Std.seqedges g returns all edges of graph g in an unspecified order
val number_of_edges : t -> intnumber_of_edges g returns the size of a graph g.
val number_of_nodes : t -> intnumber_of_nodes g returns the order of a graph g
All graphs provides a common interface for any opaque data structure
include Regular.Std.Opaque.S with type t := t
include Core_kernel.Comparable.S with type t := t
include Base.Comparable.S with type t := t
val comparator : (t, comparator_witness) Base__Comparator.comparatormodule Map :
Core_kernel.Map.S
with type Key.t = t
with type Key.comparator_witness = comparator_witnessmodule Set :
Core_kernel.Set.S
with type Elt.t = t
with type Elt.comparator_witness = comparator_witnessinclude Core_kernel.Hashable.S with type t := t
module Table : Core_kernel.Hashtbl.S with type key = tmodule Hash_set : Core_kernel.Hash_set.S with type elt = tmodule Hash_queue : Core_kernel.Hash_queue.S with type key = tAll graphs are printable.
include Regular.Std.Printable.S with type t := t
val to_string : t -> stringto_string x returns a human-readable representation of x
val str : unit -> t -> stringstr () t is formatted output function that matches "%a" conversion format specifier in functions, that prints to string, e.g., sprintf, failwithf, errorf and, surprisingly all Lwt printing function, including Lwt_io.printf and logging (or any other function with type ('a,unit,string,...) formatN`. Example:
Or_error.errorf "type %a is not valid for %a"
Type.str ty Exp.str expval pps : unit -> t -> stringsynonym for str
val ppo : Core_kernel.Out_channel.t -> t -> unitwill print to a standard output_channel, useful for using in printf, fprintf, etc.
val pp_seq : Stdlib.Format.formatter -> t Core_kernel.Sequence.t -> unitprints a sequence of values of type t