lean2/src/library/tactic/tactic.cpp

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/*
Copyright (c) 2013 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Author: Leonardo de Moura
*/
#include <utility>
#include <chrono>
#include <string>
#include "util/sstream.h"
#include "util/interrupt.h"
#include "util/lazy_list_fn.h"
#include "library/tactic/tactic_exception.h"
#include "library/tactic/tactic.h"
namespace lean {
tactic & tactic::operator=(tactic const & s) {
LEAN_COPY_REF(tactic, s);
}
tactic & tactic::operator=(tactic && s) {
LEAN_MOVE_REF(tactic, s);
}
expr tactic::solve(environment const & env, io_state const & io, proof_state const & s) {
proof_state_seq r = operator()(env, io, s);
auto p = r.pull();
if (!p)
throw exception("tactic failed to solve input");
proof_state final = p->first;
assignment a(final.get_menv());
proof_map m;
return final.get_proof_builder()(m, env, a);
}
expr tactic::solve(environment const & env, io_state const & io, context const & ctx, expr const & t) {
proof_state s = to_proof_state(env, ctx, t);
return solve(env, io, s);
}
tactic id_tactic() {
return mk_tactic([](environment const &, io_state const &, proof_state const & s) -> proof_state_seq {
return to_proof_state_seq(s);
});
}
tactic fail_tactic() {
return mk_tactic([](environment const &, io_state const &, proof_state const &) -> proof_state_seq {
return proof_state_seq();
});
}
tactic now_tactic() {
return mk_tactic([](environment const &, io_state const &, proof_state const & s) -> proof_state_seq {
if (!empty(s.get_goals()))
return proof_state_seq();
else
return to_proof_state_seq(s);
});
}
tactic trace_tactic(std::string const & msg) {
return mk_tactic([=](environment const &, io_state const & io, proof_state const & s) -> proof_state_seq {
return mk_proof_state_seq([=]() {
io.get_diagnostic_channel() << msg << "\n";
io.get_diagnostic_channel().get_stream().flush();
return some(mk_pair(s, proof_state_seq()));
});
});
}
tactic trace_tactic(sstream const & msg) {
return trace_tactic(msg.str());
}
tactic trace_tactic(char const * msg) {
return trace_tactic(std::string(msg));
}
tactic assumption_tactic() {
return mk_simple_tactic([](environment const &, io_state const &, proof_state const & s) -> proof_state {
list<std::pair<name, expr>> proofs;
goals new_goals = map_goals(s, [&](name const & ng, goal const & g) -> goal {
expr const & c = g.get_conclusion();
expr pr;
for (auto const & p : g.get_hypotheses()) {
check_interrupted();
if (p.second == c) {
pr = mk_constant(p.first);
break;
}
}
if (pr) {
proofs.emplace_front(ng, pr);
return goal();
} else {
return g;
}
});
proof_builder p = s.get_proof_builder();
proof_builder new_p = mk_proof_builder([=](proof_map const & m, environment const & env, assignment const & a) -> expr {
proof_map new_m(m);
for (auto const & np : proofs) {
new_m.insert(np.first, np.second);
}
return p(new_m, env, a);
});
return proof_state(s, new_goals, new_p);
});
}
tactic then(tactic t1, tactic t2) {
return mk_tactic([=](environment const & env, io_state const & io, proof_state const & s1) -> proof_state_seq {
tactic _t1(t1);
return map_append(_t1(env, io, s1), [=](proof_state const & s2) {
check_interrupted();
tactic _t2(t2);
return _t2(env, io, s2);
});
});
}
tactic orelse(tactic t1, tactic t2) {
return mk_tactic([=](environment const & env, io_state const & io, proof_state const & s) -> proof_state_seq {
tactic _t1(t1);
tactic _t2(t2);
return orelse(_t1(env, io, s), _t2(env, io, s));
});
}
tactic try_for(tactic t, unsigned ms, unsigned check_ms) {
if (check_ms == 0)
check_ms = 1;
return mk_tactic([=](environment const & env, io_state const & io, proof_state const & s) -> proof_state_seq {
tactic _t(t);
return timeout(_t(env, io, s), ms, check_ms);
});
}
tactic append(tactic t1, tactic t2) {
return mk_tactic([=](environment const & env, io_state const & io, proof_state const & s) -> proof_state_seq {
tactic _t1(t1);
tactic _t2(t2);
return append(_t1(env, io, s), _t2(env, io, s));
});
}
tactic interleave(tactic t1, tactic t2) {
return mk_tactic([=](environment const & env, io_state const & io, proof_state const & s) -> proof_state_seq {
tactic _t1(t1);
tactic _t2(t2);
return interleave(_t1(env, io, s), _t2(env, io, s));
});
}
tactic par(tactic t1, tactic t2, unsigned check_ms) {
return mk_tactic([=](environment const & env, io_state const & io, proof_state const & s) -> proof_state_seq {
tactic _t1(t1);
tactic _t2(t2);
return par(_t1(env, io, s), _t2(env, io, s), check_ms);
});
}
tactic repeat(tactic t) {
return mk_tactic([=](environment const & env, io_state const & io, proof_state const & s1) -> proof_state_seq {
tactic t1(t);
proof_state_seq r = t1(env, io, s1);
auto p = r.pull();
if (!p) {
return to_proof_state_seq(s1);
} else {
return map_append(to_proof_state_seq(p), [=](proof_state const & s2) {
check_interrupted();
tactic t2 = repeat(t1);
return t2(env, io, s2);
});
}
});
}
tactic repeat_at_most(tactic t, unsigned k) {
return mk_tactic([=](environment const & env, io_state const & io, proof_state const & s1) -> proof_state_seq {
if (k == 0)
return to_proof_state_seq(s1);
tactic t1(t);
proof_state_seq r = t1(env, io, s1);
auto p = r.pull();
if (!p) {
return to_proof_state_seq(s1);
} else {
return map_append(to_proof_state_seq(p), [=](proof_state const & s2) {
check_interrupted();
tactic t2 = repeat_at_most(t1, k - 1);
return t2(env, io, s2);
});
}
});
}
tactic take(tactic t, unsigned k) {
return mk_tactic([=](environment const & env, io_state const & io, proof_state const & s) -> proof_state_seq {
tactic _t(t);
return take(k, _t(env, io, s));
});
}
tactic force(tactic t) {
return mk_tactic([=](environment const & env, io_state const & io, proof_state const & s) -> proof_state_seq {
tactic _t(t);
proof_state_seq r = _t(env, io, s);
buffer<proof_state> buf;
for_each(r, [&](proof_state const & s2) {
buf.push_back(s2);
check_interrupted();
});
return to_lazy(to_list(buf.begin(), buf.end()));
});
}
}