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Add documentation about deterministic automaton and its possible representations (formal, graphic, .dot and C). Link: https://lkml.kernel.org/r/387edaed87630bd5eb37c4275045dfd229700aa6.1659052063.git.bristot@kernel.org Cc: Wim Van Sebroeck <wim@linux-watchdog.org> Cc: Guenter Roeck <linux@roeck-us.net> Cc: Jonathan Corbet <corbet@lwn.net> Cc: Ingo Molnar <mingo@redhat.com> Cc: Thomas Gleixner <tglx@linutronix.de> Cc: Peter Zijlstra <peterz@infradead.org> Cc: Will Deacon <will@kernel.org> Cc: Catalin Marinas <catalin.marinas@arm.com> Cc: Marco Elver <elver@google.com> Cc: Dmitry Vyukov <dvyukov@google.com> Cc: "Paul E. McKenney" <paulmck@kernel.org> Cc: Shuah Khan <skhan@linuxfoundation.org> Cc: Gabriele Paoloni <gpaoloni@redhat.com> Cc: Juri Lelli <juri.lelli@redhat.com> Cc: Clark Williams <williams@redhat.com> Cc: Tao Zhou <tao.zhou@linux.dev> Cc: Randy Dunlap <rdunlap@infradead.org> Cc: linux-doc@vger.kernel.org Cc: linux-kernel@vger.kernel.org Cc: linux-trace-devel@vger.kernel.org Signed-off-by: Daniel Bristot de Oliveira <bristot@kernel.org> Signed-off-by: Steven Rostedt (Google) <rostedt@goodmis.org>
185 lines
6.3 KiB
ReStructuredText
185 lines
6.3 KiB
ReStructuredText
Deterministic Automata
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======================
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Formally, a deterministic automaton, denoted by G, is defined as a quintuple:
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*G* = { *X*, *E*, *f*, x\ :subscript:`0`, X\ :subscript:`m` }
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where:
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- *X* is the set of states;
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- *E* is the finite set of events;
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- x\ :subscript:`0` is the initial state;
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- X\ :subscript:`m` (subset of *X*) is the set of marked (or final) states.
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- *f* : *X* x *E* -> *X* $ is the transition function. It defines the state
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transition in the occurrence of an event from *E* in the state *X*. In the
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special case of deterministic automata, the occurrence of the event in *E*
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in a state in *X* has a deterministic next state from *X*.
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For example, a given automaton named 'wip' (wakeup in preemptive) can
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be defined as:
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- *X* = { ``preemptive``, ``non_preemptive``}
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- *E* = { ``preempt_enable``, ``preempt_disable``, ``sched_waking``}
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- x\ :subscript:`0` = ``preemptive``
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- X\ :subscript:`m` = {``preemptive``}
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- *f* =
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- *f*\ (``preemptive``, ``preempt_disable``) = ``non_preemptive``
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- *f*\ (``non_preemptive``, ``sched_waking``) = ``non_preemptive``
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- *f*\ (``non_preemptive``, ``preempt_enable``) = ``preemptive``
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One of the benefits of this formal definition is that it can be presented
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in multiple formats. For example, using a *graphical representation*, using
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vertices (nodes) and edges, which is very intuitive for *operating system*
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practitioners, without any loss.
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The previous 'wip' automaton can also be represented as::
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preempt_enable
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+---------------------------------+
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v |
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#============# preempt_disable +------------------+
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--> H preemptive H -----------------> | non_preemptive |
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#============# +------------------+
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^ |
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| sched_waking |
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+--------------+
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Deterministic Automaton in C
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----------------------------
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In the paper "Efficient formal verification for the Linux kernel",
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the authors present a simple way to represent an automaton in C that can
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be used as regular code in the Linux kernel.
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For example, the 'wip' automata can be presented as (augmented with comments)::
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/* enum representation of X (set of states) to be used as index */
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enum states {
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preemptive = 0,
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non_preemptive,
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state_max
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};
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#define INVALID_STATE state_max
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/* enum representation of E (set of events) to be used as index */
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enum events {
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preempt_disable = 0,
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preempt_enable,
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sched_waking,
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event_max
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};
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struct automaton {
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char *state_names[state_max]; // X: the set of states
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char *event_names[event_max]; // E: the finite set of events
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unsigned char function[state_max][event_max]; // f: transition function
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unsigned char initial_state; // x_0: the initial state
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bool final_states[state_max]; // X_m: the set of marked states
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};
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struct automaton aut = {
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.state_names = {
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"preemptive",
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"non_preemptive"
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},
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.event_names = {
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"preempt_disable",
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"preempt_enable",
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"sched_waking"
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},
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.function = {
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{ non_preemptive, INVALID_STATE, INVALID_STATE },
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{ INVALID_STATE, preemptive, non_preemptive },
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},
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.initial_state = preemptive,
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.final_states = { 1, 0 },
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};
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The *transition function* is represented as a matrix of states (lines) and
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events (columns), and so the function *f* : *X* x *E* -> *X* can be solved
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in O(1). For example::
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next_state = automaton_wip.function[curr_state][event];
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Graphviz .dot format
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--------------------
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The Graphviz open-source tool can produce the graphical representation
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of an automaton using the (textual) DOT language as the source code.
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The DOT format is widely used and can be converted to many other formats.
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For example, this is the 'wip' model in DOT::
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digraph state_automaton {
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{node [shape = circle] "non_preemptive"};
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{node [shape = plaintext, style=invis, label=""] "__init_preemptive"};
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{node [shape = doublecircle] "preemptive"};
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{node [shape = circle] "preemptive"};
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"__init_preemptive" -> "preemptive";
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"non_preemptive" [label = "non_preemptive"];
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"non_preemptive" -> "non_preemptive" [ label = "sched_waking" ];
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"non_preemptive" -> "preemptive" [ label = "preempt_enable" ];
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"preemptive" [label = "preemptive"];
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"preemptive" -> "non_preemptive" [ label = "preempt_disable" ];
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{ rank = min ;
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"__init_preemptive";
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"preemptive";
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}
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}
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This DOT format can be transformed into a bitmap or vectorial image
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using the dot utility, or into an ASCII art using graph-easy. For
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instance::
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$ dot -Tsvg -o wip.svg wip.dot
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$ graph-easy wip.dot > wip.txt
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dot2c
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-----
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dot2c is a utility that can parse a .dot file containing an automaton as
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in the example above and automatically convert it to the C representation
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presented in [3].
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For example, having the previous 'wip' model into a file named 'wip.dot',
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the following command will transform the .dot file into the C
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representation (previously shown) in the 'wip.h' file::
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$ dot2c wip.dot > wip.h
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The 'wip.h' content is the code sample in section 'Deterministic Automaton
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in C'.
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Remarks
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-------
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The automata formalism allows modeling discrete event systems (DES) in
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multiple formats, suitable for different applications/users.
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For example, the formal description using set theory is better suitable
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for automata operations, while the graphical format for human interpretation;
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and computer languages for machine execution.
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References
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----------
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Many textbooks cover automata formalism. For a brief introduction see::
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O'Regan, Gerard. Concise guide to software engineering. Springer,
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Cham, 2017.
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For a detailed description, including operations, and application on Discrete
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Event Systems (DES), see::
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Cassandras, Christos G., and Stephane Lafortune, eds. Introduction to discrete
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event systems. Boston, MA: Springer US, 2008.
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For the C representation in kernel, see::
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De Oliveira, Daniel Bristot; Cucinotta, Tommaso; De Oliveira, Romulo
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Silva. Efficient formal verification for the Linux kernel. In:
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International Conference on Software Engineering and Formal Methods.
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Springer, Cham, 2019. p. 315-332.
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