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<!DOCTYPE html PUBLIC "-//W3C//DTD XHTML 1.0 Strict//EN"
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<title>UseAuto: Theory and Practice of Automation in Coq Proofs</title>
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<h1 class="libtitle">UseAuto<span class="subtitle">Theory and Practice of Automation in Coq Proofs</span></h1>
<div class="code code-tight">
</div>
<div class="doc">
</div>
<div class="code code-tight">
<br/>
<span class="comment">(* $Date: 2013-07-17 16:19:11 -0400 (Wed, 17 Jul 2013) $ *)</span><br/>
<span class="comment">(* Chapter maintained by Arthur Chargueraud *)</span><br/>
<br/>
</div>
<div class="doc">
In a machine-checked proof, every single detail has to be
justified. This can result in huge proof scripts. Fortunately,
Coq comes with a proof-search mechanism and with several decision
procedures that enable the system to automatically synthesize
simple pieces of proof. Automation is very powerful when set up
appropriately. The purpose of this chapter is to explain the
basics of working of automation.
<div class="paragraph"> </div>
The chapter is organized in two parts. The first part focuses on a
general mechanism called "proof search." In short, proof search
consists in naively trying to apply lemmas and assumptions in all
possible ways. The second part describes "decision procedures",
which are tactics that are very good at solving proof obligations
that fall in some particular fragment of the logic of Coq.
<div class="paragraph"> </div>
Many of the examples used in this chapter consist of small lemmas
that have been made up to illustrate particular aspects of automation.
These examples are completely independent from the rest of the Software
Foundations course. This chapter also contains some bigger examples
which are used to explain how to use automation in realistic proofs.
These examples are taken from other chapters of the course (mostly
from STLC), and the proofs that we present make use of the tactics
from the library <span class="inlinecode"><span class="id" type="var">LibTactics.v</span></span>, which is presented in the chapter
<span class="inlinecode"><span class="id" type="var">UseTactics</span></span>.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Require</span> <span class="id" type="keyword">Import</span> <span class="id" type="var">LibTactics</span>.<br/>
<br/>
</div>
<div class="doc">
<a name="lab994"></a><h1 class="section">Basic Features of Proof Search</h1>
<div class="paragraph"> </div>
The idea of proof search is to replace a sequence of tactics
applying lemmas and assumptions with a call to a single tactic,
for example <span class="inlinecode"><span class="id" type="tactic">auto</span></span>. This form of proof automation saves a lot of
effort. It typically leads to much shorter proof scripts, and to
scripts that are typically more robust to change. If one makes a
little change to a definition, a proof that exploits automation
probably won't need to be modified at all. Of course, using too
much automation is a bad idea. When a proof script no longer
records the main arguments of a proof, it becomes difficult to fix
it when it gets broken after a change in a definition. Overall, a
reasonable use of automation is generally a big win, as it saves a
lot of time both in building proof scripts and in subsequently
maintaining those proof scripts.
</div>
<div class="code code-tight">
<br/>
</div>
<div class="doc">
<a name="lab995"></a><h2 class="section">Strength of Proof Search</h2>
<div class="paragraph"> </div>
We are going to study four proof-search tactics: <span class="inlinecode"><span class="id" type="tactic">auto</span></span>, <span class="inlinecode"><span class="id" type="tactic">eauto</span></span>,
<span class="inlinecode"><span class="id" type="var">iauto</span></span> and <span class="inlinecode"><span class="id" type="var">jauto</span></span>. The tactics <span class="inlinecode"><span class="id" type="tactic">auto</span></span> and <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> are builtin
in Coq. The tactic <span class="inlinecode"><span class="id" type="var">iauto</span></span> is a shorthand for the builtin tactic
<span class="inlinecode"><span class="id" type="tactic">try</span></span> <span class="inlinecode"><span class="id" type="var">solve</span></span> <span class="inlinecode">[<span class="id" type="tactic">intuition</span></span> <span class="inlinecode"><span class="id" type="tactic">eauto</span>]</span>. The tactic <span class="inlinecode"><span class="id" type="var">jauto</span></span> is defined in
the library <span class="inlinecode"><span class="id" type="var">LibTactics</span></span>, and simply performs some preprocessing
of the goal before calling <span class="inlinecode"><span class="id" type="tactic">eauto</span></span>. The goal of this chapter is
to explain the general principles of proof search and to give
rule of thumbs for guessing which of the four tactics mentioned
above is best suited for solving a given goal.
<div class="paragraph"> </div>
Proof search is a compromise between efficiency and
expressiveness, that is, a tradeoff between how complex goals the
tactic can solve and how much time the tactic requires for
terminating. The tactic <span class="inlinecode"><span class="id" type="tactic">auto</span></span> builds proofs only by using the
basic tactics <span class="inlinecode"><span class="id" type="tactic">reflexivity</span></span>, <span class="inlinecode"><span class="id" type="tactic">assumption</span></span>, and <span class="inlinecode"><span class="id" type="tactic">apply</span></span>. The tactic
<span class="inlinecode"><span class="id" type="tactic">eauto</span></span> can also exploit <span class="inlinecode"><span class="id" type="tactic">eapply</span></span>. The tactic <span class="inlinecode"><span class="id" type="var">jauto</span></span> extends
<span class="inlinecode"><span class="id" type="tactic">eauto</span></span> by being able to open conjunctions and existentials that
occur in the context. The tactic <span class="inlinecode"><span class="id" type="var">iauto</span></span> is able to deal with
conjunctions, disjunctions, and negation in a quite clever way;
however it is not able to open existentials from the context.
Also, <span class="inlinecode"><span class="id" type="var">iauto</span></span> usually becomes very slow when the goal involves
several disjunctions.
<div class="paragraph"> </div>
Note that proof search tactics never perform any rewriting
step (tactics <span class="inlinecode"><span class="id" type="tactic">rewrite</span></span>, <span class="inlinecode"><span class="id" type="tactic">subst</span></span>), nor any case analysis on an
arbitrary data structure or predicate (tactics <span class="inlinecode"><span class="id" type="tactic">destruct</span></span> and
<span class="inlinecode"><span class="id" type="tactic">inversion</span></span>), nor any proof by induction (tactic <span class="inlinecode"><span class="id" type="tactic">induction</span></span>). So,
proof search is really intended to automate the final steps from
the various branches of a proof. It is not able to discover the
overall structure of a proof.
</div>
<div class="code code-tight">
<br/>
</div>
<div class="doc">
<a name="lab996"></a><h2 class="section">Basics</h2>
<div class="paragraph"> </div>
The tactic <span class="inlinecode"><span class="id" type="tactic">auto</span></span> is able to solve a goal that can be proved
using a sequence of <span class="inlinecode"><span class="id" type="tactic">intros</span></span>, <span class="inlinecode"><span class="id" type="tactic">apply</span></span>, <span class="inlinecode"><span class="id" type="tactic">assumption</span></span>, and <span class="inlinecode"><span class="id" type="tactic">reflexivity</span></span>.
Two examples follow. The first one shows the ability for
<span class="inlinecode"><span class="id" type="tactic">auto</span></span> to call <span class="inlinecode"><span class="id" type="tactic">reflexivity</span></span> at any time. In fact, calling
<span class="inlinecode"><span class="id" type="tactic">reflexivity</span></span> is always the first thing that <span class="inlinecode"><span class="id" type="tactic">auto</span></span> tries to do.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">solving_by_reflexivity</span> : <br/>
2 + 3 = 5.<br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="tactic">auto</span>. <span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
The second example illustrates a proof where a sequence of
two calls to <span class="inlinecode"><span class="id" type="tactic">apply</span></span> are needed. The goal is to prove that
if <span class="inlinecode"><span class="id" type="var">Q</span></span> <span class="inlinecode"><span class="id" type="var">n</span></span> implies <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode"><span class="id" type="var">n</span></span> for any <span class="inlinecode"><span class="id" type="var">n</span></span> and if <span class="inlinecode"><span class="id" type="var">Q</span></span> <span class="inlinecode"><span class="id" type="var">n</span></span> holds for any <span class="inlinecode"><span class="id" type="var">n</span></span>,
then <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">2</span> holds.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">solving_by_apply</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">P</span> <span class="id" type="var">Q</span> : <span class="id" type="var">nat</span><span style="font-family: arial;">→</span><span class="id" type="keyword">Prop</span>),<br/>
(<span style="font-family: arial;">∀</span><span class="id" type="var">n</span>, <span class="id" type="var">Q</span> <span class="id" type="var">n</span> <span style="font-family: arial;">→</span> <span class="id" type="var">P</span> <span class="id" type="var">n</span>) <span style="font-family: arial;">→</span> <br/>
(<span style="font-family: arial;">∀</span><span class="id" type="var">n</span>, <span class="id" type="var">Q</span> <span class="id" type="var">n</span>) <span style="font-family: arial;">→</span><br/>
<span class="id" type="var">P</span> 2.<br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="tactic">auto</span>. <span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
We can ask <span class="inlinecode"><span class="id" type="tactic">auto</span></span> to tell us what proof it came up with,
by invoking <span class="inlinecode"><span class="id" type="var">info_auto</span></span> in place of <span class="inlinecode"><span class="id" type="tactic">auto</span></span>.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">solving_by_apply'</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">P</span> <span class="id" type="var">Q</span> : <span class="id" type="var">nat</span><span style="font-family: arial;">→</span><span class="id" type="keyword">Prop</span>),<br/>
(<span style="font-family: arial;">∀</span><span class="id" type="var">n</span>, <span class="id" type="var">Q</span> <span class="id" type="var">n</span> <span style="font-family: arial;">→</span> <span class="id" type="var">P</span> <span class="id" type="var">n</span>) <span style="font-family: arial;">→</span> <br/>
(<span style="font-family: arial;">∀</span><span class="id" type="var">n</span>, <span class="id" type="var">Q</span> <span class="id" type="var">n</span>) <span style="font-family: arial;">→</span><br/>
<span class="id" type="var">P</span> 2.<br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="var">info_auto</span>. <span class="id" type="keyword">Qed</span>.<br/>
<span class="comment">(* The output is: <span class="inlinecode"><span class="id" type="tactic">intro</span></span> <span class="inlinecode"><span class="id" type="var">P</span>;</span> <span class="inlinecode"><span class="id" type="tactic">intro</span></span> <span class="inlinecode"><span class="id" type="var">Q</span>;</span> <span class="inlinecode"><span class="id" type="tactic">intro</span></span> <span class="inlinecode"><span class="id" type="var">H</span>;</span> *)</span><br/>
<span class="comment">(* followed with <span class="inlinecode"><span class="id" type="tactic">intro</span></span> <span class="inlinecode"><span class="id" type="var">H0</span>;</span> <span class="inlinecode"><span class="id" type="var">simple</span></span> <span class="inlinecode"><span class="id" type="tactic">apply</span></span> <span class="inlinecode"><span class="id" type="var">H</span>;</span> <span class="inlinecode"><span class="id" type="var">simple</span></span> <span class="inlinecode"><span class="id" type="tactic">apply</span></span> <span class="inlinecode"><span class="id" type="var">H0</span></span>. *)</span><br/>
<span class="comment">(* i.e., the sequence <span class="inlinecode"><span class="id" type="tactic">intros</span></span> <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode"><span class="id" type="var">Q</span></span> <span class="inlinecode"><span class="id" type="var">H</span></span> <span class="inlinecode"><span class="id" type="var">H0</span>;</span> <span class="inlinecode"><span class="id" type="tactic">apply</span></span> <span class="inlinecode"><span class="id" type="var">H</span>;</span> <span class="inlinecode"><span class="id" type="tactic">apply</span></span> <span class="inlinecode"><span class="id" type="var">H0</span></span>. *)</span><br/>
<br/>
</div>
<div class="doc">
The tactic <span class="inlinecode"><span class="id" type="tactic">auto</span></span> can invoke <span class="inlinecode"><span class="id" type="tactic">apply</span></span> but not <span class="inlinecode"><span class="id" type="tactic">eapply</span></span>. So, <span class="inlinecode"><span class="id" type="tactic">auto</span></span>
cannot exploit lemmas whose instantiation cannot be directly
deduced from the proof goal. To exploit such lemmas, one needs to
invoke the tactic <span class="inlinecode"><span class="id" type="tactic">eauto</span></span>, which is able to call <span class="inlinecode"><span class="id" type="tactic">eapply</span></span>.
<div class="paragraph"> </div>
In the following example, the first hypothesis asserts that <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode"><span class="id" type="var">n</span></span>
is true when <span class="inlinecode"><span class="id" type="var">Q</span></span> <span class="inlinecode"><span class="id" type="var">m</span></span> is true for some <span class="inlinecode"><span class="id" type="var">m</span></span>, and the goal is to prove
that <span class="inlinecode"><span class="id" type="var">Q</span></span> <span class="inlinecode">1</span> implies <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">2</span>. This implication follows direction from
the hypothesis by instantiating <span class="inlinecode"><span class="id" type="var">m</span></span> as the value <span class="inlinecode">1</span>. The
following proof script shows that <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> successfully solves the
goal, whereas <span class="inlinecode"><span class="id" type="tactic">auto</span></span> is not able to do so.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">solving_by_eapply</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">P</span> <span class="id" type="var">Q</span> : <span class="id" type="var">nat</span><span style="font-family: arial;">→</span><span class="id" type="keyword">Prop</span>),<br/>
(<span style="font-family: arial;">∀</span><span class="id" type="var">n</span> <span class="id" type="var">m</span>, <span class="id" type="var">Q</span> <span class="id" type="var">m</span> <span style="font-family: arial;">→</span> <span class="id" type="var">P</span> <span class="id" type="var">n</span>) <span style="font-family: arial;">→</span><br/>
<span class="id" type="var">Q</span> 1 <span style="font-family: arial;">→</span> <span class="id" type="var">P</span> 2.<br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="tactic">auto</span>. <span class="id" type="tactic">eauto</span>. <span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
Remark: Again, we can use <span class="inlinecode"><span class="id" type="var">info_eauto</span></span> to see what proof <span class="inlinecode"><span class="id" type="tactic">eauto</span></span>
comes up with.
</div>
<div class="code code-tight">
<br/>
</div>
<div class="doc">
<a name="lab997"></a><h2 class="section">Conjunctions</h2>
<div class="paragraph"> </div>
So far, we've seen that <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> is stronger than <span class="inlinecode"><span class="id" type="tactic">auto</span></span> in the
sense that it can deal with <span class="inlinecode"><span class="id" type="tactic">eapply</span></span>. In the same way, we are going
to see how <span class="inlinecode"><span class="id" type="var">jauto</span></span> and <span class="inlinecode"><span class="id" type="var">iauto</span></span> are stronger than <span class="inlinecode"><span class="id" type="tactic">auto</span></span> and <span class="inlinecode"><span class="id" type="tactic">eauto</span></span>
in the sense that they provide better support for conjunctions.
<div class="paragraph"> </div>
The tactics <span class="inlinecode"><span class="id" type="tactic">auto</span></span> and <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> can prove a goal of the form
<span class="inlinecode"><span class="id" type="var">F</span></span> <span class="inlinecode"><span style="font-family: arial;">∧</span></span> <span class="inlinecode"><span class="id" type="var">F'</span></span>, where <span class="inlinecode"><span class="id" type="var">F</span></span> and <span class="inlinecode"><span class="id" type="var">F'</span></span> are two propositions, as soon as
both <span class="inlinecode"><span class="id" type="var">F</span></span> and <span class="inlinecode"><span class="id" type="var">F'</span></span> can be proved in the current context.
An example follows.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">solving_conj_goal</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">P</span> : <span class="id" type="var">nat</span><span style="font-family: arial;">→</span><span class="id" type="keyword">Prop</span>) (<span class="id" type="var">F</span> : <span class="id" type="keyword">Prop</span>),<br/>
(<span style="font-family: arial;">∀</span><span class="id" type="var">n</span>, <span class="id" type="var">P</span> <span class="id" type="var">n</span>) <span style="font-family: arial;">→</span> <span class="id" type="var">F</span> <span style="font-family: arial;">→</span> <span class="id" type="var">F</span> <span style="font-family: arial;">∧</span> <span class="id" type="var">P</span> 2.<br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="tactic">auto</span>. <span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
However, when an assumption is a conjunction, <span class="inlinecode"><span class="id" type="tactic">auto</span></span> and <span class="inlinecode"><span class="id" type="tactic">eauto</span></span>
are not able to exploit this conjunction. It can be quite
surprising at first that <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> can prove very complex goals but
that it fails to prove that <span class="inlinecode"><span class="id" type="var">F</span></span> <span class="inlinecode"><span style="font-family: arial;">∧</span></span> <span class="inlinecode"><span class="id" type="var">F'</span></span> implies <span class="inlinecode"><span class="id" type="var">F</span></span>. The tactics
<span class="inlinecode"><span class="id" type="var">iauto</span></span> and <span class="inlinecode"><span class="id" type="var">jauto</span></span> are able to decompose conjunctions from the context.
Here is an example.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">solving_conj_hyp</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">F</span> <span class="id" type="var">F'</span> : <span class="id" type="keyword">Prop</span>),<br/>
<span class="id" type="var">F</span> <span style="font-family: arial;">∧</span> <span class="id" type="var">F'</span> <span style="font-family: arial;">→</span> <span class="id" type="var">F</span>.<br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="tactic">auto</span>. <span class="id" type="tactic">eauto</span>. <span class="id" type="var">jauto</span>. <span class="comment">(* or <span class="inlinecode"><span class="id" type="var">iauto</span></span> *)</span> <span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
The tactic <span class="inlinecode"><span class="id" type="var">jauto</span></span> is implemented by first calling a
pre-processing tactic called <span class="inlinecode"><span class="id" type="var">jauto_set</span></span>, and then calling
<span class="inlinecode"><span class="id" type="tactic">eauto</span></span>. So, to understand how <span class="inlinecode"><span class="id" type="var">jauto</span></span> works, one can directly
call the tactic <span class="inlinecode"><span class="id" type="var">jauto_set</span></span>.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">solving_conj_hyp'</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">F</span> <span class="id" type="var">F'</span> : <span class="id" type="keyword">Prop</span>),<br/>
<span class="id" type="var">F</span> <span style="font-family: arial;">∧</span> <span class="id" type="var">F'</span> <span style="font-family: arial;">→</span> <span class="id" type="var">F</span>.<br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="tactic">intros</span>. <span class="id" type="var">jauto_set</span>. <span class="id" type="tactic">eauto</span>. <span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
Next is a more involved goal that can be solved by <span class="inlinecode"><span class="id" type="var">iauto</span></span> and
<span class="inlinecode"><span class="id" type="var">jauto</span></span>.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">solving_conj_more</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">P</span> <span class="id" type="var">Q</span> <span class="id" type="var">R</span> : <span class="id" type="var">nat</span><span style="font-family: arial;">→</span><span class="id" type="keyword">Prop</span>) (<span class="id" type="var">F</span> : <span class="id" type="keyword">Prop</span>),<br/>
(<span class="id" type="var">F</span> <span style="font-family: arial;">∧</span> (<span style="font-family: arial;">∀</span><span class="id" type="var">n</span> <span class="id" type="var">m</span>, (<span class="id" type="var">Q</span> <span class="id" type="var">m</span> <span style="font-family: arial;">∧</span> <span class="id" type="var">R</span> <span class="id" type="var">n</span>) <span style="font-family: arial;">→</span> <span class="id" type="var">P</span> <span class="id" type="var">n</span>)) <span style="font-family: arial;">→</span><br/>
(<span class="id" type="var">F</span> <span style="font-family: arial;">→</span> <span class="id" type="var">R</span> 2) <span style="font-family: arial;">→</span> <br/>
<span class="id" type="var">Q</span> 1 <span style="font-family: arial;">→</span><br/>
<span class="id" type="var">P</span> 2 <span style="font-family: arial;">∧</span> <span class="id" type="var">F</span>.<br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="var">jauto</span>. <span class="comment">(* or <span class="inlinecode"><span class="id" type="var">iauto</span></span> *)</span> <span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
The strategy of <span class="inlinecode"><span class="id" type="var">iauto</span></span> and <span class="inlinecode"><span class="id" type="var">jauto</span></span> is to run a global analysis of
the top-level conjunctions, and then call <span class="inlinecode"><span class="id" type="tactic">eauto</span></span>. For this
reason, those tactics are not good at dealing with conjunctions
that occur as the conclusion of some universally quantified
hypothesis. The following example illustrates a general weakness
of Coq proof search mechanisms.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">solving_conj_hyp_forall</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">P</span> <span class="id" type="var">Q</span> : <span class="id" type="var">nat</span><span style="font-family: arial;">→</span><span class="id" type="keyword">Prop</span>),<br/>
(<span style="font-family: arial;">∀</span><span class="id" type="var">n</span>, <span class="id" type="var">P</span> <span class="id" type="var">n</span> <span style="font-family: arial;">∧</span> <span class="id" type="var">Q</span> <span class="id" type="var">n</span>) <span style="font-family: arial;">→</span> <span class="id" type="var">P</span> 2.<br/>
<span class="id" type="keyword">Proof</span>.<br/>
<span class="id" type="tactic">auto</span>. <span class="id" type="tactic">eauto</span>. <span class="id" type="var">iauto</span>. <span class="id" type="var">jauto</span>.<br/>
<span class="comment">(* Nothing works, so we have to do some of the work by hand *)</span><br/>
<span class="id" type="tactic">intros</span>. <span class="id" type="tactic">destruct</span> (<span class="id" type="var">H</span> 2). <span class="id" type="tactic">auto</span>.<br/>
<span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
This situation is slightly disappointing, since automation is
able to prove the following goal, which is very similar. The
only difference is that the universal quantification has been
distributed over the conjunction.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">solved_by_jauto</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">P</span> <span class="id" type="var">Q</span> : <span class="id" type="var">nat</span><span style="font-family: arial;">→</span><span class="id" type="keyword">Prop</span>) (<span class="id" type="var">F</span> : <span class="id" type="keyword">Prop</span>),<br/>
(<span style="font-family: arial;">∀</span><span class="id" type="var">n</span>, <span class="id" type="var">P</span> <span class="id" type="var">n</span>) <span style="font-family: arial;">∧</span> (<span style="font-family: arial;">∀</span><span class="id" type="var">n</span>, <span class="id" type="var">Q</span> <span class="id" type="var">n</span>) <span style="font-family: arial;">→</span> <span class="id" type="var">P</span> 2.<br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="var">jauto</span>. <span class="comment">(* or <span class="inlinecode"><span class="id" type="var">iauto</span></span> *)</span> <span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
<a name="lab998"></a><h2 class="section">Disjunctions</h2>
<div class="paragraph"> </div>
The tactics <span class="inlinecode"><span class="id" type="tactic">auto</span></span> and <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> can handle disjunctions that
occur in the goal.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">solving_disj_goal</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">F</span> <span class="id" type="var">F'</span> : <span class="id" type="keyword">Prop</span>),<br/>
<span class="id" type="var">F</span> <span style="font-family: arial;">→</span> <span class="id" type="var">F</span> <span style="font-family: arial;">∨</span> <span class="id" type="var">F'</span>.<br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="tactic">auto</span>. <span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
However, only <span class="inlinecode"><span class="id" type="var">iauto</span></span> is able to automate reasoning on the
disjunctions that appear in the context. For example, <span class="inlinecode"><span class="id" type="var">iauto</span></span> can
prove that <span class="inlinecode"><span class="id" type="var">F</span></span> <span class="inlinecode"><span style="font-family: arial;">∨</span></span> <span class="inlinecode"><span class="id" type="var">F'</span></span> entails <span class="inlinecode"><span class="id" type="var">F'</span></span> <span class="inlinecode"><span style="font-family: arial;">∨</span></span> <span class="inlinecode"><span class="id" type="var">F</span></span>.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">solving_disj_hyp</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">F</span> <span class="id" type="var">F'</span> : <span class="id" type="keyword">Prop</span>),<br/>
<span class="id" type="var">F</span> <span style="font-family: arial;">∨</span> <span class="id" type="var">F'</span> <span style="font-family: arial;">→</span> <span class="id" type="var">F'</span> <span style="font-family: arial;">∨</span> <span class="id" type="var">F</span>.<br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="tactic">auto</span>. <span class="id" type="tactic">eauto</span>. <span class="id" type="var">jauto</span>. <span class="id" type="var">iauto</span>. <span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
More generally, <span class="inlinecode"><span class="id" type="var">iauto</span></span> can deal with complex combinations of
conjunctions, disjunctions, and negations. Here is an example.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">solving_tauto</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">F1</span> <span class="id" type="var">F2</span> <span class="id" type="var">F3</span> : <span class="id" type="keyword">Prop</span>),<br/>
((¬<span class="id" type="var">F1</span> <span style="font-family: arial;">∧</span> <span class="id" type="var">F3</span>) <span style="font-family: arial;">∨</span> (<span class="id" type="var">F2</span> <span style="font-family: arial;">∧</span> ¬<span class="id" type="var">F3</span>)) <span style="font-family: arial;">→</span><br/>
(<span class="id" type="var">F2</span> <span style="font-family: arial;">→</span> <span class="id" type="var">F1</span>) <span style="font-family: arial;">→</span><br/>
(<span class="id" type="var">F2</span> <span style="font-family: arial;">→</span> <span class="id" type="var">F3</span>) <span style="font-family: arial;">→</span> <br/>
¬<span class="id" type="var">F2</span>.<br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="var">iauto</span>. <span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
However, the ability of <span class="inlinecode"><span class="id" type="var">iauto</span></span> to automatically perform a case
analysis on disjunctions comes with a downside: <span class="inlinecode"><span class="id" type="var">iauto</span></span> may be
very slow. If the context involves several hypotheses with
disjunctions, <span class="inlinecode"><span class="id" type="var">iauto</span></span> typically generates an exponential number of
subgoals on which <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> is called. One major advantage of <span class="inlinecode"><span class="id" type="var">jauto</span></span>
compared with <span class="inlinecode"><span class="id" type="var">iauto</span></span> is that it never spends time performing this
kind of case analyses.
</div>
<div class="code code-tight">
<br/>
</div>
<div class="doc">
<a name="lab999"></a><h2 class="section">Existentials</h2>
<div class="paragraph"> </div>
The tactics <span class="inlinecode"><span class="id" type="tactic">eauto</span></span>, <span class="inlinecode"><span class="id" type="var">iauto</span></span>, and <span class="inlinecode"><span class="id" type="var">jauto</span></span> can prove goals whose
conclusion is an existential. For example, if the goal is <span class="inlinecode"><span style="font-family: arial;">∃</span></span>
<span class="inlinecode"><span class="id" type="var">x</span>,</span> <span class="inlinecode"><span class="id" type="var">f</span></span> <span class="inlinecode"><span class="id" type="var">x</span></span>, the tactic <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> introduces an existential variable,
say <span class="inlinecode">?25</span>, in place of <span class="inlinecode"><span class="id" type="var">x</span></span>. The remaining goal is <span class="inlinecode"><span class="id" type="var">f</span></span> <span class="inlinecode">?25</span>, and
<span class="inlinecode"><span class="id" type="tactic">eauto</span></span> tries to solve this goal, allowing itself to instantiate
<span class="inlinecode">?25</span> with any appropriate value. For example, if an assumption <span class="inlinecode"><span class="id" type="var">f</span></span>
<span class="inlinecode">2</span> is available, then the variable <span class="inlinecode">?25</span> gets instantiated with
<span class="inlinecode">2</span> and the goal is solved, as shown below.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">solving_exists_goal</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">f</span> : <span class="id" type="var">nat</span><span style="font-family: arial;">→</span><span class="id" type="keyword">Prop</span>),<br/>
<span class="id" type="var">f</span> 2 <span style="font-family: arial;">→</span> <span style="font-family: arial;">∃</span><span class="id" type="var">x</span>, <span class="id" type="var">f</span> <span class="id" type="var">x</span>.<br/>
<span class="id" type="keyword">Proof</span>.<br/>
<span class="id" type="tactic">auto</span>. <span class="comment">(* observe that <span class="inlinecode"><span class="id" type="tactic">auto</span></span> does not deal with existentials, *)</span><br/>
<span class="id" type="tactic">eauto</span>. <span class="comment">(* whereas <span class="inlinecode"><span class="id" type="tactic">eauto</span></span>, <span class="inlinecode"><span class="id" type="var">iauto</span></span> and <span class="inlinecode"><span class="id" type="var">jauto</span></span> solve the goal *)</span><br/>
<span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
A major strength of <span class="inlinecode"><span class="id" type="var">jauto</span></span> over the other proof search tactics is
that it is able to exploit the existentially-quantified
hypotheses, i.e., those of the form <span class="inlinecode"><span style="font-family: arial;">∃</span></span> <span class="inlinecode"><span class="id" type="var">x</span>,</span> <span class="inlinecode"><span class="id" type="var">P</span></span>.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">solving_exists_hyp</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">f</span> <span class="id" type="var">g</span> : <span class="id" type="var">nat</span><span style="font-family: arial;">→</span><span class="id" type="keyword">Prop</span>),<br/>
(<span style="font-family: arial;">∀</span><span class="id" type="var">x</span>, <span class="id" type="var">f</span> <span class="id" type="var">x</span> <span style="font-family: arial;">→</span> <span class="id" type="var">g</span> <span class="id" type="var">x</span>) <span style="font-family: arial;">→</span><br/>
(<span style="font-family: arial;">∃</span><span class="id" type="var">a</span>, <span class="id" type="var">f</span> <span class="id" type="var">a</span>) <span style="font-family: arial;">→</span> <br/>
(<span style="font-family: arial;">∃</span><span class="id" type="var">a</span>, <span class="id" type="var">g</span> <span class="id" type="var">a</span>).<br/>
<span class="id" type="keyword">Proof</span>.<br/>
<span class="id" type="tactic">auto</span>. <span class="id" type="tactic">eauto</span>. <span class="id" type="var">iauto</span>. <span class="comment">(* All of these tactics fail, *)</span><br/>
<span class="id" type="var">jauto</span>. <span class="comment">(* whereas <span class="inlinecode"><span class="id" type="var">jauto</span></span> succeeds. *)</span><br/>
<span class="comment">(* For the details, run <span class="inlinecode"><span class="id" type="tactic">intros</span>.</span> <span class="inlinecode"><span class="id" type="var">jauto_set</span>.</span> <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> *)</span><br/>
<span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
<a name="lab1000"></a><h2 class="section">Negation</h2>
<div class="paragraph"> </div>
The tactics <span class="inlinecode"><span class="id" type="tactic">auto</span></span> and <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> suffer from some limitations with
respect to the manipulation of negations, mostly related to the
fact that negation, written <span class="inlinecode">¬</span> <span class="inlinecode"><span class="id" type="var">P</span></span>, is defined as <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode"><span style="font-family: arial;">→</span></span> <span class="inlinecode"><span class="id" type="var">False</span></span> but
that the unfolding of this definition is not performed
automatically. Consider the following example.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">negation_study_1</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">P</span> : <span class="id" type="var">nat</span><span style="font-family: arial;">→</span><span class="id" type="keyword">Prop</span>),<br/>
<span class="id" type="var">P</span> 0 <span style="font-family: arial;">→</span> (<span style="font-family: arial;">∀</span><span class="id" type="var">x</span>, ¬ <span class="id" type="var">P</span> <span class="id" type="var">x</span>) <span style="font-family: arial;">→</span> <span class="id" type="var">False</span>.<br/>
<span class="id" type="keyword">Proof</span>.<br/>
<span class="id" type="tactic">intros</span> <span class="id" type="var">P</span> <span class="id" type="var">H0</span> <span class="id" type="var">HX</span>.<br/>
<span class="id" type="tactic">eauto</span>. <span class="comment">(* It fails to see that <span class="inlinecode"><span class="id" type="var">HX</span></span> applies *)</span><br/>
<span class="id" type="tactic">unfold</span> <span class="id" type="var">not</span> <span class="id" type="keyword">in</span> ×. <span class="id" type="tactic">eauto</span>.<br/>
<span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
For this reason, the tactics <span class="inlinecode"><span class="id" type="var">iauto</span></span> and <span class="inlinecode"><span class="id" type="var">jauto</span></span> systematically
invoke <span class="inlinecode"><span class="id" type="tactic">unfold</span></span> <span class="inlinecode"><span class="id" type="var">not</span></span> <span class="inlinecode"><span class="id" type="keyword">in</span></span> <span class="inlinecode">×</span> as part of their pre-processing. So,
they are able to solve the previous goal right away.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">negation_study_2</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">P</span> : <span class="id" type="var">nat</span><span style="font-family: arial;">→</span><span class="id" type="keyword">Prop</span>),<br/>
<span class="id" type="var">P</span> 0 <span style="font-family: arial;">→</span> (<span style="font-family: arial;">∀</span><span class="id" type="var">x</span>, ¬ <span class="id" type="var">P</span> <span class="id" type="var">x</span>) <span style="font-family: arial;">→</span> <span class="id" type="var">False</span>.<br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="var">jauto</span>. <span class="comment">(* or <span class="inlinecode"><span class="id" type="var">iauto</span></span> *)</span> <span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
We will come back later on to the behavior of proof search with
respect to the unfolding of definitions.
</div>
<div class="code code-tight">
<br/>
</div>
<div class="doc">
<a name="lab1001"></a><h2 class="section">Equalities</h2>
<div class="paragraph"> </div>
Coq's proof-search feature is not good at exploiting equalities.
It can do very basic operations, like exploiting reflexivity
and symmetry, but that's about it. Here is a simple example
that <span class="inlinecode"><span class="id" type="tactic">auto</span></span> can solve, by first calling <span class="inlinecode"><span class="id" type="tactic">symmetry</span></span> and then
applying the hypothesis.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">equality_by_auto</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">f</span> <span class="id" type="var">g</span> : <span class="id" type="var">nat</span><span style="font-family: arial;">→</span><span class="id" type="keyword">Prop</span>),<br/>
(<span style="font-family: arial;">∀</span><span class="id" type="var">x</span>, <span class="id" type="var">f</span> <span class="id" type="var">x</span> = <span class="id" type="var">g</span> <span class="id" type="var">x</span>) <span style="font-family: arial;">→</span> <span class="id" type="var">g</span> 2 = <span class="id" type="var">f</span> 2.<br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="tactic">auto</span>. <span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
To automate more advanced reasoning on equalities, one should
rather try to use the tactic <span class="inlinecode"><span class="id" type="tactic">congruence</span></span>, which is presented at
the end of this chapter in the "Decision Procedures" section.
</div>
<div class="code code-tight">
<br/>
</div>
<div class="doc">
<a name="lab1002"></a><h1 class="section">How Proof Search Works</h1>
</div>
<div class="code code-space">
<br/>
</div>
<div class="doc">
<a name="lab1003"></a><h2 class="section">Search Depth</h2>
<div class="paragraph"> </div>
The tactic <span class="inlinecode"><span class="id" type="tactic">auto</span></span> works as follows. It first tries to call
<span class="inlinecode"><span class="id" type="tactic">reflexivity</span></span> and <span class="inlinecode"><span class="id" type="tactic">assumption</span></span>. If one of these calls solves the
goal, the job is done. Otherwise <span class="inlinecode"><span class="id" type="tactic">auto</span></span> tries to apply the most
recently introduced assumption that can be applied to the goal
without producing and error. This application produces
subgoals. There are two possible cases. If the sugboals produced
can be solved by a recursive call to <span class="inlinecode"><span class="id" type="tactic">auto</span></span>, then the job is done.
Otherwise, if this application produces at least one subgoal that
<span class="inlinecode"><span class="id" type="tactic">auto</span></span> cannot solve, then <span class="inlinecode"><span class="id" type="tactic">auto</span></span> starts over by trying to apply
the second most recently introduced assumption. It continues in a
similar fashion until it finds a proof or until no assumption
remains to be tried.
<div class="paragraph"> </div>
It is very important to have a clear idea of the backtracking
process involved in the execution of the <span class="inlinecode"><span class="id" type="tactic">auto</span></span> tactic; otherwise
its behavior can be quite puzzling. For example, <span class="inlinecode"><span class="id" type="tactic">auto</span></span> is not
able to solve the following triviality.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">search_depth_0</span> : <br/>
<span class="id" type="var">True</span> <span style="font-family: arial;">∧</span> <span class="id" type="var">True</span> <span style="font-family: arial;">∧</span> <span class="id" type="var">True</span> <span style="font-family: arial;">∧</span> <span class="id" type="var">True</span> <span style="font-family: arial;">∧</span> <span class="id" type="var">True</span> <span style="font-family: arial;">∧</span> <span class="id" type="var">True</span>.<br/>
<span class="id" type="keyword">Proof</span>.<br/>
<span class="id" type="tactic">auto</span>.<br/>
<span class="id" type="keyword">Abort</span>.<br/>
<br/>
</div>
<div class="doc">
The reason <span class="inlinecode"><span class="id" type="tactic">auto</span></span> fails to solve the goal is because there are
too many conjunctions. If there had been only five of them, <span class="inlinecode"><span class="id" type="tactic">auto</span></span>
would have successfully solved the proof, but six is too many.
The tactic <span class="inlinecode"><span class="id" type="tactic">auto</span></span> limits the number of lemmas and hypotheses
that can be applied in a proof, so as to ensure that the proof
search eventually terminates. By default, the maximal number
of steps is five. One can specify a different bound, writing
for example <span class="inlinecode"><span class="id" type="tactic">auto</span></span> <span class="inlinecode">6</span> to search for a proof involving at most
six steps. For example, <span class="inlinecode"><span class="id" type="tactic">auto</span></span> <span class="inlinecode">6</span> would solve the previous lemma.
(Similarly, one can invoke <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> <span class="inlinecode">6</span> or <span class="inlinecode"><span class="id" type="tactic">intuition</span></span> <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> <span class="inlinecode">6</span>.)
The argument <span class="inlinecode"><span class="id" type="var">n</span></span> of <span class="inlinecode"><span class="id" type="tactic">auto</span></span> <span class="inlinecode"><span class="id" type="var">n</span></span> is called the "search depth."
The tactic <span class="inlinecode"><span class="id" type="tactic">auto</span></span> is simply defined as a shorthand for <span class="inlinecode"><span class="id" type="tactic">auto</span></span> <span class="inlinecode">5</span>.
<div class="paragraph"> </div>
The behavior of <span class="inlinecode"><span class="id" type="tactic">auto</span></span> <span class="inlinecode"><span class="id" type="var">n</span></span> can be summarized as follows. It first
tries to solve the goal using <span class="inlinecode"><span class="id" type="tactic">reflexivity</span></span> and <span class="inlinecode"><span class="id" type="tactic">assumption</span></span>. If
this fails, it tries to apply a hypothesis (or a lemma that has
been registered in the hint database), and this application
produces a number of sugoals. The tactic <span class="inlinecode"><span class="id" type="tactic">auto</span></span> <span class="inlinecode">(<span class="id" type="var">n</span>-1)</span> is then
called on each of those subgoals. If all the subgoals are solved,
the job is completed, otherwise <span class="inlinecode"><span class="id" type="tactic">auto</span></span> <span class="inlinecode"><span class="id" type="var">n</span></span> tries to apply a
different hypothesis.
<div class="paragraph"> </div>
During the process, <span class="inlinecode"><span class="id" type="tactic">auto</span></span> <span class="inlinecode"><span class="id" type="var">n</span></span> calls <span class="inlinecode"><span class="id" type="tactic">auto</span></span> <span class="inlinecode">(<span class="id" type="var">n</span>-1)</span>, which in turn
might call <span class="inlinecode"><span class="id" type="tactic">auto</span></span> <span class="inlinecode">(<span class="id" type="var">n</span>-2)</span>, and so on. The tactic <span class="inlinecode"><span class="id" type="tactic">auto</span></span> <span class="inlinecode">0</span> only
tries <span class="inlinecode"><span class="id" type="tactic">reflexivity</span></span> and <span class="inlinecode"><span class="id" type="tactic">assumption</span></span>, and does not try to apply
any lemma. Overall, this means that when the maximal number of
steps allowed has been exceeded, the <span class="inlinecode"><span class="id" type="tactic">auto</span></span> tactic stops searching
and backtracks to try and investigate other paths.
<div class="paragraph"> </div>
The following lemma admits a unique proof that involves exactly
three steps. So, <span class="inlinecode"><span class="id" type="tactic">auto</span></span> <span class="inlinecode"><span class="id" type="var">n</span></span> proves this goal iff <span class="inlinecode"><span class="id" type="var">n</span></span> is greater than
three.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">search_depth_1</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">P</span> : <span class="id" type="var">nat</span><span style="font-family: arial;">→</span><span class="id" type="keyword">Prop</span>),<br/>
<span class="id" type="var">P</span> 0 <span style="font-family: arial;">→</span><br/>
(<span class="id" type="var">P</span> 0 <span style="font-family: arial;">→</span> <span class="id" type="var">P</span> 1) <span style="font-family: arial;">→</span><br/>
(<span class="id" type="var">P</span> 1 <span style="font-family: arial;">→</span> <span class="id" type="var">P</span> 2) <span style="font-family: arial;">→</span><br/>
(<span class="id" type="var">P</span> 2).<br/>
<span class="id" type="keyword">Proof</span>.<br/>
<span class="id" type="tactic">auto</span> 0. <span class="comment">(* does not find the proof *)</span><br/>
<span class="id" type="tactic">auto</span> 1. <span class="comment">(* does not find the proof *)</span><br/>
<span class="id" type="tactic">auto</span> 2. <span class="comment">(* does not find the proof *)</span><br/>
<span class="id" type="tactic">auto</span> 3. <span class="comment">(* finds the proof *)</span><br/>
<span class="comment">(* more generally, <span class="inlinecode"><span class="id" type="tactic">auto</span></span> <span class="inlinecode"><span class="id" type="var">n</span></span> solves the goal if <span class="inlinecode"><span class="id" type="var">n</span></span> <span class="inlinecode">≥</span> <span class="inlinecode">3</span> *)</span><br/>
<span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
We can generalize the example by introducing an assumption
asserting that <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode"><span class="id" type="var">k</span></span> is derivable from <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">(<span class="id" type="var">k</span>-1)</span> for all <span class="inlinecode"><span class="id" type="var">k</span></span>,
and keep the assumption <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">0</span>. The tactic <span class="inlinecode"><span class="id" type="tactic">auto</span></span>, which is the
same as <span class="inlinecode"><span class="id" type="tactic">auto</span></span> <span class="inlinecode">5</span>, is able to derive <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode"><span class="id" type="var">k</span></span> for all values of <span class="inlinecode"><span class="id" type="var">k</span></span>
less than 5. For example, it can prove <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">4</span>.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">search_depth_3</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">P</span> : <span class="id" type="var">nat</span><span style="font-family: arial;">→</span><span class="id" type="keyword">Prop</span>),<br/>
<span class="comment">(* Hypothesis H1: *)</span> (<span class="id" type="var">P</span> 0) <span style="font-family: arial;">→</span> <br/>
<span class="comment">(* Hypothesis H2: *)</span> (<span style="font-family: arial;">∀</span><span class="id" type="var">k</span>, <span class="id" type="var">P</span> (<span class="id" type="var">k</span>-1) <span style="font-family: arial;">→</span> <span class="id" type="var">P</span> <span class="id" type="var">k</span>) <span style="font-family: arial;">→</span> <br/>
<span class="comment">(* Goal: *)</span> (<span class="id" type="var">P</span> 4).<br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="tactic">auto</span>. <span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
However, to prove <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">5</span>, one needs to call at least <span class="inlinecode"><span class="id" type="tactic">auto</span></span> <span class="inlinecode">6</span>.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">search_depth_4</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">P</span> : <span class="id" type="var">nat</span><span style="font-family: arial;">→</span><span class="id" type="keyword">Prop</span>),<br/>
<span class="comment">(* Hypothesis H1: *)</span> (<span class="id" type="var">P</span> 0) <span style="font-family: arial;">→</span> <br/>
<span class="comment">(* Hypothesis H2: *)</span> (<span style="font-family: arial;">∀</span><span class="id" type="var">k</span>, <span class="id" type="var">P</span> (<span class="id" type="var">k</span>-1) <span style="font-family: arial;">→</span> <span class="id" type="var">P</span> <span class="id" type="var">k</span>) <span style="font-family: arial;">→</span> <br/>
<span class="comment">(* Goal: *)</span> (<span class="id" type="var">P</span> 5).<br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="tactic">auto</span>. <span class="id" type="tactic">auto</span> 6. <span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
Because <span class="inlinecode"><span class="id" type="tactic">auto</span></span> looks for proofs at a limited depth, there are
cases where <span class="inlinecode"><span class="id" type="tactic">auto</span></span> can prove a goal <span class="inlinecode"><span class="id" type="var">F</span></span> and can prove a goal
<span class="inlinecode"><span class="id" type="var">F'</span></span> but cannot prove <span class="inlinecode"><span class="id" type="var">F</span></span> <span class="inlinecode"><span style="font-family: arial;">∧</span></span> <span class="inlinecode"><span class="id" type="var">F'</span></span>. In the following example,
<span class="inlinecode"><span class="id" type="tactic">auto</span></span> can prove <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">4</span> but it is not able to prove <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">4</span> <span class="inlinecode"><span style="font-family: arial;">∧</span></span> <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">4</span>,
because the splitting of the conjunction consumes one proof step.
To prove the conjunction, one needs to increase the search depth,
using at least <span class="inlinecode"><span class="id" type="tactic">auto</span></span> <span class="inlinecode">6</span>.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">search_depth_5</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">P</span> : <span class="id" type="var">nat</span><span style="font-family: arial;">→</span><span class="id" type="keyword">Prop</span>),<br/>
<span class="comment">(* Hypothesis H1: *)</span> (<span class="id" type="var">P</span> 0) <span style="font-family: arial;">→</span> <br/>
<span class="comment">(* Hypothesis H2: *)</span> (<span style="font-family: arial;">∀</span><span class="id" type="var">k</span>, <span class="id" type="var">P</span> (<span class="id" type="var">k</span>-1) <span style="font-family: arial;">→</span> <span class="id" type="var">P</span> <span class="id" type="var">k</span>) <span style="font-family: arial;">→</span> <br/>
<span class="comment">(* Goal: *)</span> (<span class="id" type="var">P</span> 4 <span style="font-family: arial;">∧</span> <span class="id" type="var">P</span> 4).<br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="tactic">auto</span>. <span class="id" type="tactic">auto</span> 6. <span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
<a name="lab1004"></a><h2 class="section">Backtracking</h2>
<div class="paragraph"> </div>
In the previous section, we have considered proofs where
at each step there was a unique assumption that <span class="inlinecode"><span class="id" type="tactic">auto</span></span>
could apply. In general, <span class="inlinecode"><span class="id" type="tactic">auto</span></span> can have several choices
at every step. The strategy of <span class="inlinecode"><span class="id" type="tactic">auto</span></span> consists of trying all
of the possibilities (using a depth-first search exploration).
<div class="paragraph"> </div>
To illustrate how automation works, we are going to extend the
previous example with an additional assumption asserting that
<span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode"><span class="id" type="var">k</span></span> is also derivable from <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">(<span class="id" type="var">k</span>+1)</span>. Adding this hypothesis
offers a new possibility that <span class="inlinecode"><span class="id" type="tactic">auto</span></span> could consider at every step.
<div class="paragraph"> </div>
There exists a special command that one can use for tracing
all the steps that proof-search considers. To view such a
trace, one should write <span class="inlinecode"><span class="id" type="var">debug</span></span> <span class="inlinecode"><span class="id" type="tactic">eauto</span></span>. (For some reason, the
command <span class="inlinecode"><span class="id" type="var">debug</span></span> <span class="inlinecode"><span class="id" type="tactic">auto</span></span> does not exist, so we have to use the
command <span class="inlinecode"><span class="id" type="var">debug</span></span> <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> instead.)
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">working_of_auto_1</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">P</span> : <span class="id" type="var">nat</span><span style="font-family: arial;">→</span><span class="id" type="keyword">Prop</span>),<br/>
<span class="comment">(* Hypothesis H1: *)</span> (<span class="id" type="var">P</span> 0) <span style="font-family: arial;">→</span> <br/>
<span class="comment">(* Hypothesis H2: *)</span> (<span style="font-family: arial;">∀</span><span class="id" type="var">k</span>, <span class="id" type="var">P</span> (<span class="id" type="var">k</span>+1) <span style="font-family: arial;">→</span> <span class="id" type="var">P</span> <span class="id" type="var">k</span>) <span style="font-family: arial;">→</span> <br/>
<span class="comment">(* Hypothesis H3: *)</span> (<span style="font-family: arial;">∀</span><span class="id" type="var">k</span>, <span class="id" type="var">P</span> (<span class="id" type="var">k</span>-1) <span style="font-family: arial;">→</span> <span class="id" type="var">P</span> <span class="id" type="var">k</span>) <span style="font-family: arial;">→</span><br/>
<span class="comment">(* Goal: *)</span> (<span class="id" type="var">P</span> 2).<br/>
<span class="comment">(* Uncomment "debug" in the following line to see the debug trace: *)</span><br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="tactic">intros</span> <span class="id" type="var">P</span> <span class="id" type="var">H1</span> <span class="id" type="var">H2</span> <span class="id" type="var">H3</span>. <span class="comment">(* debug *)</span> <span class="id" type="tactic">eauto</span>. <span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
The output message produced by <span class="inlinecode"><span class="id" type="var">debug</span></span> <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> is as follows.
<pre>
depth=5
depth=4 apply H3
depth=3 apply H3
depth=3 exact H1
</pre>
The depth indicates the value of <span class="inlinecode"><span class="id" type="var">n</span></span> with which <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> <span class="inlinecode"><span class="id" type="var">n</span></span> is
called. The tactics shown in the message indicate that the first
thing that <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> has tried to do is to apply <span class="inlinecode"><span class="id" type="var">H3</span></span>. The effect of
applying <span class="inlinecode"><span class="id" type="var">H3</span></span> is to replace the goal <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">2</span> with the goal <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">1</span>.
Then, again, <span class="inlinecode"><span class="id" type="var">H3</span></span> has been applied, changing the goal <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">1</span> into
<span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">0</span>. At that point, the goal was exactly the hypothesis <span class="inlinecode"><span class="id" type="var">H1</span></span>.
<div class="paragraph"> </div>
It seems that <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> was quite lucky there, as it never even
tried to use the hypothesis <span class="inlinecode"><span class="id" type="var">H2</span></span> at any time. The reason is that
<span class="inlinecode"><span class="id" type="tactic">auto</span></span> always tries to use the most recently introduced hypothesis
first, and <span class="inlinecode"><span class="id" type="var">H3</span></span> is a more recent hypothesis than <span class="inlinecode"><span class="id" type="var">H2</span></span> in the goal.
So, let's permute the hypotheses <span class="inlinecode"><span class="id" type="var">H2</span></span> and <span class="inlinecode"><span class="id" type="var">H3</span></span> and see what
happens.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Lemma</span> <span class="id" type="var">working_of_auto_2</span> : <span style="font-family: arial;">∀</span>(<span class="id" type="var">P</span> : <span class="id" type="var">nat</span><span style="font-family: arial;">→</span><span class="id" type="keyword">Prop</span>),<br/>
<span class="comment">(* Hypothesis H1: *)</span> (<span class="id" type="var">P</span> 0) <span style="font-family: arial;">→</span> <br/>
<span class="comment">(* Hypothesis H3: *)</span> (<span style="font-family: arial;">∀</span><span class="id" type="var">k</span>, <span class="id" type="var">P</span> (<span class="id" type="var">k</span>-1) <span style="font-family: arial;">→</span> <span class="id" type="var">P</span> <span class="id" type="var">k</span>) <span style="font-family: arial;">→</span><br/>
<span class="comment">(* Hypothesis H2: *)</span> (<span style="font-family: arial;">∀</span><span class="id" type="var">k</span>, <span class="id" type="var">P</span> (<span class="id" type="var">k</span>+1) <span style="font-family: arial;">→</span> <span class="id" type="var">P</span> <span class="id" type="var">k</span>) <span style="font-family: arial;">→</span> <br/>
<span class="comment">(* Goal: *)</span> (<span class="id" type="var">P</span> 2).<br/>
<span class="id" type="keyword">Proof</span>. <span class="id" type="tactic">intros</span> <span class="id" type="var">P</span> <span class="id" type="var">H1</span> <span class="id" type="var">H3</span> <span class="id" type="var">H2</span>. <span class="comment">(* debug *)</span> <span class="id" type="tactic">eauto</span>. <span class="id" type="keyword">Qed</span>.<br/>
<br/>
</div>
<div class="doc">
This time, the output message suggests that the proof search
investigates many possibilities. Replacing <span class="inlinecode"><span class="id" type="var">debug</span></span> <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> with
<span class="inlinecode"><span class="id" type="var">info_eauto</span></span>, we observe that the proof that <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> comes up
with is actually not the simplest one.
<span class="inlinecode"><span class="id" type="tactic">apply</span></span> <span class="inlinecode"><span class="id" type="var">H2</span>;</span> <span class="inlinecode"><span class="id" type="tactic">apply</span></span> <span class="inlinecode"><span class="id" type="var">H3</span>;</span> <span class="inlinecode"><span class="id" type="tactic">apply</span></span> <span class="inlinecode"><span class="id" type="var">H3</span>;</span> <span class="inlinecode"><span class="id" type="tactic">apply</span></span> <span class="inlinecode"><span class="id" type="var">H3</span>;</span> <span class="inlinecode"><span class="id" type="tactic">exact</span></span> <span class="inlinecode"><span class="id" type="var">H1</span></span>
This proof goes through the proof obligation <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">3</span>, even though
it is not any useful. The following tree drawing describes
all the goals that automation has been through.
<pre>
|5||4||3||2||1||0| -- below, tabulation indicates the depth
[P 2]
-> [P 3]
-> [P 4]
-> [P 5]
-> [P 6]
-> [P 7]
-> [P 5]
-> [P 4]
-> [P 5]
-> [P 3]
--> [P 3]
-> [P 4]
-> [P 5]
-> [P 3]
-> [P 2]
-> [P 3]
-> [P 1]
-> [P 2]
-> [P 3]
-> [P 4]
-> [P 5]
-> [P 3]
-> [P 2]
-> [P 3]
-> [P 1]
-> [P 1]
-> [P 2]
-> [P 3]
-> [P 1]
-> [P 0]
-> !! Done !!
</pre>
The first few lines read as follows. To prove <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">2</span>, <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> <span class="inlinecode">5</span>
has first tried to apply <span class="inlinecode"><span class="id" type="var">H2</span></span>, producing the subgoal <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">3</span>.
To solve it, <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> <span class="inlinecode">4</span> has tried again to apply <span class="inlinecode"><span class="id" type="var">H2</span></span>, producing
the goal <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">4</span>. Similarly, the search goes through <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">5</span>, <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">6</span>
and <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">7</span>. When reaching <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">7</span>, the tactic <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> <span class="inlinecode">0</span> is called
but as it is not allowed to try and apply any lemma, it fails.
So, we come back to the goal <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">6</span>, and try this time to apply
hypothesis <span class="inlinecode"><span class="id" type="var">H3</span></span>, producing the subgoal <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">5</span>. Here again,
<span class="inlinecode"><span class="id" type="tactic">eauto</span></span> <span class="inlinecode">0</span> fails to solve this goal.
<div class="paragraph"> </div>
The process goes on and on, until backtracking to <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">3</span> and trying
to apply <span class="inlinecode"><span class="id" type="var">H2</span></span> three times in a row, going through <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">2</span> and <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">1</span>
and <span class="inlinecode"><span class="id" type="var">P</span></span> <span class="inlinecode">0</span>. This search tree explains why <span class="inlinecode"><span class="id" type="tactic">eauto</span></span> came up with a
proof starting with <span class="inlinecode"><span class="id" type="tactic">apply</span></span> <span class="inlinecode"><span class="id" type="var">H2</span></span>.
</div>
<div class="code code-tight">
<br/>
</div>
<div class="doc">
<a name="lab1005"></a><h2 class="section">Adding Hints</h2>
<div class="paragraph"> </div>
By default, <span class="inlinecode"><span class="id" type="tactic">auto</span></span> (and <span class="inlinecode"><span class="id" type="tactic">eauto</span></span>) only tries to apply the
hypotheses that appear in the proof context. There are two
possibilities for telling <span class="inlinecode"><span class="id" type="tactic">auto</span></span> to exploit a lemma that have
been proved previously: either adding the lemma as an assumption
just before calling <span class="inlinecode"><span class="id" type="tactic">auto</span></span>, or adding the lemma as a hint, so
that it can be used by every calls to <span class="inlinecode"><span class="id" type="tactic">auto</span></span>.
<div class="paragraph"> </div>
The first possibility is useful to have <span class="inlinecode"><span class="id" type="tactic">auto</span></span> exploit a lemma
that only serves at this particular point. To add the lemma as
hypothesis, one can type <span class="inlinecode"><span class="id" type="tactic">generalize</span></span> <span class="inlinecode"><span class="id" type="var">mylemma</span>;</span> <span class="inlinecode"><span class="id" type="tactic">intros</span></span>, or simply
<span class="inlinecode"><span class="id" type="var">lets</span>:</span> <span class="inlinecode"><span class="id" type="var">mylemma</span></span> (the latter requires <span class="inlinecode"><span class="id" type="var">LibTactics.v</span></span>).
<div class="paragraph"> </div>
The second possibility is useful for lemmas that need to be
exploited several times. The syntax for adding a lemma as a hint
is <span class="inlinecode"><span class="id" type="keyword">Hint</span></span> <span class="inlinecode"><span class="id" type="keyword">Resolve</span></span> <span class="inlinecode"><span class="id" type="var">mylemma</span></span>. For example, the lemma asserting than
any number is less than or equal to itself, <span class="inlinecode"><span style="font-family: arial;">∀</span></span> <span class="inlinecode"><span class="id" type="var">x</span>,</span> <span class="inlinecode"><span class="id" type="var">x</span></span> <span class="inlinecode">≤</span> <span class="inlinecode"><span class="id" type="var">x</span></span>,
called <span class="inlinecode"><span class="id" type="var">Le.le_refl</span></span> in the Coq standard library, can be added as a
hint as follows.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Hint</span> <span class="id" type="keyword">Resolve</span> <span class="id" type="var">Le.le_refl</span>.<br/>
<br/>
</div>
<div class="doc">
A convenient shorthand for adding all the constructors of an
inductive datatype as hints is the command <span class="inlinecode"><span class="id" type="keyword">Hint</span></span> <span class="inlinecode"><span class="id" type="var">Constructors</span></span>
<span class="inlinecode"><span class="id" type="var">mydatatype</span></span>.
<div class="paragraph"> </div>
Warning: some lemmas, such as transitivity results, should
not be added as hints as they would very badly affect the
performance of proof search. The description of this problem
and the presentation of a general work-around for transitivity
lemmas appear further on.
</div>
<div class="code code-tight">
<br/>
</div>
<div class="doc">
<a name="lab1006"></a><h2 class="section">Integration of Automation in Tactics</h2>
<div class="paragraph"> </div>
The library "LibTactics" introduces a convenient feature for
invoking automation after calling a tactic. In short, it suffices
to add the symbol star (<span class="inlinecode">×</span>) to the name of a tactic. For example,
<span class="inlinecode"><span class="id" type="tactic">apply</span>×</span> <span class="inlinecode"><span class="id" type="var">H</span></span> is equivalent to <span class="inlinecode"><span class="id" type="tactic">apply</span></span> <span class="inlinecode"><span class="id" type="var">H</span>;</span> <span class="inlinecode"><span class="id" type="var">auto_star</span></span>, where <span class="inlinecode"><span class="id" type="var">auto_star</span></span>
is a tactic that can be defined as needed. By default, <span class="inlinecode"><span class="id" type="var">auto_star</span></span>
first tries to solve the goal using <span class="inlinecode"><span class="id" type="tactic">auto</span></span>, and if this does not
succeed then it tries to call <span class="inlinecode"><span class="id" type="var">jauto</span></span>. Even though <span class="inlinecode"><span class="id" type="var">jauto</span></span> is
strictly stronger than <span class="inlinecode"><span class="id" type="tactic">auto</span></span>, it makes sense to call <span class="inlinecode"><span class="id" type="tactic">auto</span></span> first:
when <span class="inlinecode"><span class="id" type="tactic">auto</span></span> succeeds it may save a lot of time, and when <span class="inlinecode"><span class="id" type="tactic">auto</span></span>
fails to prove the goal, it fails very quickly.
<div class="paragraph"> </div>
The definition of <span class="inlinecode"><span class="id" type="var">auto_star</span></span>, which determines the meaning of the
star symbol, can be modified whenever needed. Simply write:
<div class="paragraph"> </div>
<div class="code code-tight">
<span class="id" type="keyword">Ltac</span> <span class="id" type="var">auto_star</span> ::= <span class="id" type="var">a_new_definition</span>.
<div class="paragraph"> </div>
</div>
Observe the use of <span class="inlinecode">::=</span> instead of <span class="inlinecode">:=</span>, which indicates that the
tactic is being rebound to a new definition. So, the default
definition is as follows.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Ltac</span> <span class="id" type="var">auto_star</span> ::= <span class="id" type="tactic">try</span> <span class="id" type="var">solve</span> [ <span class="id" type="tactic">auto</span> | <span class="id" type="var">jauto</span> ].<br/>
<br/>
</div>
<div class="doc">
Nearly all standard Coq tactics and all the tactics from
"LibTactics" can be called with a star symbol. For example, one
can invoke <span class="inlinecode"><span class="id" type="tactic">subst</span>×</span>, <span class="inlinecode"><span class="id" type="tactic">destruct</span>×</span> <span class="inlinecode"><span class="id" type="var">H</span></span>, <span class="inlinecode"><span class="id" type="var">inverts</span>×</span> <span class="inlinecode"><span class="id" type="var">H</span></span>, <span class="inlinecode"><span class="id" type="var">lets</span>×</span> <span class="inlinecode"><span class="id" type="var">I</span>:</span> <span class="inlinecode"><span class="id" type="var">H</span></span> <span class="inlinecode"><span class="id" type="var">x</span></span>,
<span class="inlinecode"><span class="id" type="var">specializes</span>×</span> <span class="inlinecode"><span class="id" type="var">H</span></span> <span class="inlinecode"><span class="id" type="var">x</span></span>, and so on... There are two notable exceptions.
The tactic <span class="inlinecode"><span class="id" type="tactic">auto</span>×</span> is just another name for the tactic
<span class="inlinecode"><span class="id" type="var">auto_star</span></span>. And the tactic <span class="inlinecode"><span class="id" type="tactic">apply</span>×</span> <span class="inlinecode"><span class="id" type="var">H</span></span> calls <span class="inlinecode"><span class="id" type="tactic">eapply</span></span> <span class="inlinecode"><span class="id" type="var">H</span></span> (or the
more powerful <span class="inlinecode"><span class="id" type="var">applys</span></span> <span class="inlinecode"><span class="id" type="var">H</span></span> if needed), and then calls <span class="inlinecode"><span class="id" type="var">auto_star</span></span>.
Note that there is no <span class="inlinecode"><span class="id" type="tactic">eapply</span>×</span> <span class="inlinecode"><span class="id" type="var">H</span></span> tactic, use <span class="inlinecode"><span class="id" type="tactic">apply</span>×</span> <span class="inlinecode"><span class="id" type="var">H</span></span>
instead.
<div class="paragraph"> </div>
In large developments, it can be convenient to use two degrees of
automation. Typically, one would use a fast tactic, like <span class="inlinecode"><span class="id" type="tactic">auto</span></span>,
and a slower but more powerful tactic, like <span class="inlinecode"><span class="id" type="var">jauto</span></span>. To allow for
a smooth coexistence of the two form of automation, <span class="inlinecode"><span class="id" type="var">LibTactics.v</span></span>
also defines a "tilde" version of tactics, like <span class="inlinecode"><span class="id" type="tactic">apply</span>¬</span> <span class="inlinecode"><span class="id" type="var">H</span></span>,
<span class="inlinecode"><span class="id" type="tactic">destruct</span>¬</span> <span class="inlinecode"><span class="id" type="var">H</span></span>, <span class="inlinecode"><span class="id" type="tactic">subst</span>¬</span>, <span class="inlinecode"><span class="id" type="tactic">auto</span>¬</span> and so on. The meaning of the
tilde symbol is described by the <span class="inlinecode"><span class="id" type="var">auto_tilde</span></span> tactic, whose
default implementation is <span class="inlinecode"><span class="id" type="tactic">auto</span></span>.
</div>
<div class="code code-tight">
<br/>
<span class="id" type="keyword">Ltac</span> <span class="id" type="var">auto_tilde</span> ::= <span class="id" type="tactic">auto</span>.<br/>
<br/>
</div>
<div class="doc">
In the examples that follow, only <span class="inlinecode"><span class="id" type="var">auto_star</span></span> is needed.
</div>
<div class="code code-tight">
<br/>
</div>
<div class="doc">
<a name="lab1007"></a><h1 class="section">Examples of Use of Automation</h1>
<div class="paragraph"> </div>
Let's see how to use proof search in practice on the main theorems
of the "Software Foundations" course, proving in particular
results such as determinism, preservation and progress.
</div>
<div class="code code-tight">
<br/>
</div>
<div class="doc">
<a name="lab1008"></a><h2 class="section">Determinism</h2>
</div>
<div class="code code-space">
<br/>
<span class="id" type="keyword">Module</span> <span class="id" type="var">DeterministicImp</span>.<br/>
<span class="id" type="keyword">Require</span> <span class="id" type="keyword">Import</span> <span class="id" type="var">Imp</span>.<br/>