aocpp/2022/21.cpp
Eric Mertens a38a105e6f cleanups
2023-04-07 09:45:55 -07:00

206 lines
5.3 KiB
C++

#include <cstdint>
#include <iostream>
#include <sstream>
#include <stdexcept>
#include <string>
#include <unordered_map>
#include <variant>
#include <vector>
#include <boost/phoenix.hpp>
#include <boost/spirit/include/qi.hpp>
#include <doctest.h>
#include <z3++.h>
#include <aocpp/Overloaded.hpp>
#include <aocpp/Startup.hpp>
namespace {
namespace phx = boost::phoenix;
namespace qi = boost::spirit::qi;
enum class Op { Add, Sub, Mul, Div };
struct Expr {
std::string lhs;
std::string rhs;
Op op;
};
struct Entry {
std::string lvalue;
std::variant<std::int64_t, Expr> rvalue;
};
using Input = std::vector<Entry>;
// Input file grammar
template <typename It>
class Grammar : public qi::grammar<It, Input()> {
qi::rule<It, std::string()> variable;
qi::rule<It, Op()> op;
qi::rule<It, Expr()> expr;
qi::rule<It, std::variant<std::int64_t, Expr>()> rhs;
qi::rule<It, Entry()> line;
qi::rule<It, Input()> input;
public:
Grammar() : Grammar::base_type{input} {
using namespace qi::labels;
variable = qi::as_string[+qi::alpha];
op =
qi::string("+") [ _val = Op::Add ] |
qi::string("-") [ _val = Op::Sub ] |
qi::string("*") [ _val = Op::Mul ] |
qi::string("/") [ _val = Op::Div ];
expr =
variable [phx::bind(&Expr::lhs, _val) = _1] >> " " >>
op [phx::bind(&Expr::op, _val) = _1] >> " " >>
variable [phx::bind(&Expr::rhs, _val) = _1];
rhs = expr | qi::long_long;
line =
variable [ phx::bind(&Entry::lvalue, _val) = _1] >> ": " >>
rhs [ phx::bind(&Entry::rvalue, _val) = _1] >> "\n";
input = *line;
}
};
/// Parse the complete input stream according to the rules defined in 'Grammar'.
/// Throws: std::runtime_error on failed parse
auto Parse(std::istream & in) -> Input
{
auto result = Input{};
auto const content = std::string{std::istreambuf_iterator{in}, {}};
auto b = content.begin(); // updated on successful parse
auto const e = content.end();
if (!qi::parse(b, e, Grammar<decltype(b)>{}, result) || b != e) {
throw std::runtime_error{"Bad input file: " + content};
}
return result;
}
auto Eval(
std::unordered_map<std::string, double> & values,
std::unordered_map<std::string, Expr> const& exprs,
std::string const& var)
-> double
{
if (auto const it = values.find(var); it != values.end()) {
return it->second;
}
auto const& [lhs,rhs,op] = exprs.at(var);
auto const l = Eval(values, exprs, lhs);
auto const r = Eval(values, exprs, rhs);
double o;
switch (op) {
case Op::Add: o = l + r; break;
case Op::Sub: o = l - r; break;
case Op::Mul: o = l * r; break;
case Op::Div: o = l / r; break;
}
values.emplace(var, o);
return o;
}
auto Part1(Input const& input) -> std::int64_t
{
std::unordered_map<std::string, double> values;
std::unordered_map<std::string, Expr> exprs;
for (auto const& entry : input) {
std::visit(overloaded {
[&](Expr const& expr) { exprs.emplace(entry.lvalue, expr); },
[&](std::int64_t val) { values.emplace(entry.lvalue, val); }
}, entry.rvalue);
}
return Eval(values, exprs, "root");
}
auto Part2(Input const& input) -> std::int64_t
{
auto ctx = z3::context{};
auto const solve_eqs = z3::tactic{ctx, "solve-eqs"};
auto const smt = z3::tactic{ctx, "smt"};
auto solver = (solve_eqs & smt).mk_solver();
std::unordered_map<std::string, z3::expr> constants;
for (auto const& entry : input) {
constants.emplace(entry.lvalue, ctx.int_const(entry.lvalue.c_str()));
}
for (auto const& entry : input) {
if (entry.lvalue == "root") {
if (auto * const expr = std::get_if<Expr>(&entry.rvalue)) {
solver.add(constants.at(expr->lhs) == constants.at(expr->rhs));
} else {
throw std::runtime_error{"malformed root"};
}
} else if (entry.lvalue != "humn") {
auto const rhs =
std::visit(overloaded {
[&](std::int64_t literal) {
return ctx.int_val(literal);
},
[&](Expr const& expr) {
auto const l = constants.at(expr.lhs);
auto const r = constants.at(expr.rhs);
switch (expr.op) {
case Op::Add: return l + r;
case Op::Sub: return l - r;
case Op::Mul: return l * r;
case Op::Div:
solver.add(l % r == 0);
return l / r;
}
}
}, entry.rvalue);
solver.add(constants.at(entry.lvalue) == rhs);
}
}
if (solver.check() != z3::sat) {
throw std::runtime_error{"no solution to part 2"};
}
return solver.get_model().eval(constants.at("humn")).get_numeral_int64();
}
} // namespace
TEST_SUITE("2022-21 examples") {
TEST_CASE("documented example") {
auto in = std::istringstream{
"root: pppw + sjmn\n"
"dbpl: 5\n"
"cczh: sllz + lgvd\n"
"zczc: 2\n"
"ptdq: humn - dvpt\n"
"dvpt: 3\n"
"lfqf: 4\n"
"humn: 5\n"
"ljgn: 2\n"
"sjmn: drzm * dbpl\n"
"sllz: 4\n"
"pppw: cczh / lfqf\n"
"lgvd: ljgn * ptdq\n"
"drzm: hmdt - zczc\n"
"hmdt: 32\n"
};
auto const input = Parse(in);
CHECK(152 == Part1(input));
CHECK(301 == Part2(input));
}
}
auto Main(std::istream & in, std::ostream & out) -> void
{
auto const input = Parse(in);
out << "Part 1: " << Part1(input) << std::endl;
out << "Part 2: " << Part2(input) << std::endl;
}