#include <cassert>
#include <iostream>
#include <iterator>
#include <list>
#include <pqxx/transaction>
#include "../test_helpers.hxx"
// Test program for libpqxx. Define and use prepared statements.
#define COMPARE_RESULTS(name, lhs, rhs) \
PQXX_CHECK_EQUAL( \
rhs, lhs, \
"Executing " name " as prepared statement yields different results.");
namespace
{
using namespace std::literals;
template<typename T> std::string stringize(pqxx::transaction_base &t, T i)
{
return stringize(t, pqxx::to_string(i));
}
// Substitute variables in raw query. This is not likely to be very robust,
// but it should do for just this test. The main shortcomings are escaping,
// and not knowing when to quote the variables.
// Note we do the replacement backwards (meaning forward_only iterators won't
// do!) to avoid substituting e.g. "$12" as "$1" first.
template<typename ITER>
std::string
subst(pqxx::transaction_base &t, std::string q, ITER patbegin, ITER patend)
{
ptrdiff_t i{distance(patbegin, patend)};
for (ITER arg{patend}; i > 0; --i)
{
--arg;
std::string const marker{"$" + pqxx::to_string(i)},
var{stringize(t, *arg)};
std::string::size_type const msz{std::size(marker)};
while (q.find(marker) != std::string::npos)
q.replace(q.find(marker), msz, var);
}
return q;
}
template<typename CNTNR>
std::string
subst(pqxx::transaction_base &t, std::string const &q, CNTNR const &patterns)
{
return subst(t, q, std::begin(patterns), std::end(patterns));
}
void test_registration_and_invocation()
{
constexpr auto count_to_5{"SELECT * FROM generate_series(1, 5)"};
pqxx::connection c;
pqxx::work tx1{c};
// Prepare a simple statement.
tx1.conn().prepare("CountToFive", count_to_5);
// The statement returns exactly what you'd expect.
COMPARE_RESULTS(
"CountToFive", tx1.exec_prepared("CountToFive"), tx1.exec(count_to_5));
// Re-preparing it is an error.
PQXX_CHECK_THROWS(
tx1.conn().prepare("CountToFive", count_to_5), pqxx::sql_error,
"Did not report re-definition of prepared statement.");
tx1.abort();
pqxx::work tx2{c};
// Executing a nonexistent prepared statement is also an error.
PQXX_CHECK_THROWS(
tx2.exec_prepared("NonexistentStatement"), pqxx::sql_error,
"Did not report invocation of nonexistent prepared statement.");
}
void test_basic_args()
{
pqxx::connection c;
c.prepare("EchoNum", "SELECT $1::int");
pqxx::work tx{c};
auto r{tx.exec_prepared("EchoNum", 7)};
PQXX_CHECK_EQUAL(
std::size(r), 1, "Did not get 1 row from prepared statement.");
PQXX_CHECK_EQUAL(std::size(r.front()), 1, "Did not get exactly one column.");
PQXX_CHECK_EQUAL(r[0][0].as<int>(), 7, "Got wrong result.");
auto rw{tx.exec_prepared1("EchoNum", 8)};
PQXX_CHECK_EQUAL(
std::size(rw), 1, "Did not get 1 column from exec_prepared1.");
PQXX_CHECK_EQUAL(rw[0].as<int>(), 8, "Got wrong result.");
}
void test_multiple_params()
{
pqxx::connection c;
c.prepare("CountSeries", "SELECT * FROM generate_series($1::int, $2::int)");
pqxx::work tx{c};
auto r{tx.exec_prepared_n(4, "CountSeries", 7, 10)};
PQXX_CHECK_EQUAL(
std::size(r), 4, "Wrong number of rows, but no error raised.");
PQXX_CHECK_EQUAL(r.front().front().as<int>(), 7, "Wrong $1.");
PQXX_CHECK_EQUAL(r.back().front().as<int>(), 10, "Wrong $2.");
c.prepare("Reversed", "SELECT * FROM generate_series($2::int, $1::int)");
r = tx.exec_prepared_n(3, "Reversed", 8, 6);
PQXX_CHECK_EQUAL(
r.front().front().as<int>(), 6, "Did parameters get reordered?");
PQXX_CHECK_EQUAL(
r.back().front().as<int>(), 8, "$2 did not come through properly.");
}
void test_nulls()
{
pqxx::connection c;
pqxx::work tx{c};
c.prepare("EchoStr", "SELECT $1::varchar");
auto rw{tx.exec_prepared1("EchoStr", nullptr)};
PQXX_CHECK(rw.front().is_null(), "nullptr did not translate to null.");
char const *n{nullptr};
rw = tx.exec_prepared1("EchoStr", n);
PQXX_CHECK(rw.front().is_null(), "Null pointer did not translate to null.");
}
void test_strings()
{
pqxx::connection c;
pqxx::work tx{c};
c.prepare("EchoStr", "SELECT $1::varchar");
auto rw{tx.exec_prepared1("EchoStr", "foo")};
PQXX_CHECK_EQUAL(
rw.front().as<std::string>(), "foo", "Wrong string result.");
char const nasty_string[]{R"--('\"\)--"};
rw = tx.exec_prepared1("EchoStr", nasty_string);
PQXX_CHECK_EQUAL(
rw.front().as<std::string>(), std::string(nasty_string),
"Prepared statement did not quote/escape correctly.");
rw = tx.exec_prepared1("EchoStr", std::string{nasty_string});
PQXX_CHECK_EQUAL(
rw.front().as<std::string>(), std::string(nasty_string),
"Quoting/escaping went wrong in std::string.");
char nonconst[]{"non-const C string"};
rw = tx.exec_prepared1("EchoStr", nonconst);
PQXX_CHECK_EQUAL(
rw.front().as<std::string>(), std::string(nonconst),
"Non-const C string passed incorrectly.");
}
void test_binary()
{
pqxx::connection c;
pqxx::work tx{c};
c.prepare("EchoBin", "SELECT $1::bytea");
constexpr char raw_bytes[]{"Binary\0bytes'\"with\tweird\xff bytes"};
std::string const input{raw_bytes, std::size(raw_bytes)};
#include "pqxx/internal/ignore-deprecated-pre.hxx"
{
pqxx::binarystring const bin{input};
auto rw{tx.exec_prepared1("EchoBin", bin)};
PQXX_CHECK_EQUAL(
pqxx::binarystring(rw[0]).str(), input,
"Binary string came out damaged.");
}
#include "pqxx/internal/ignore-deprecated-post.hxx"
{
std::basic_string<std::byte> bytes{
reinterpret_cast<std::byte const *>(raw_bytes), std::size(raw_bytes)};
auto bp{tx.exec_prepared1("EchoBin", bytes)};
auto bval{bp[0].as<std::basic_string<std::byte>>()};
PQXX_CHECK_EQUAL(
(std::string_view{
reinterpret_cast<char const *>(bval.c_str()), std::size(bval)}),
input, "Binary string parameter went wrong.");
}
// Now try it with a complex type that ultimately uses the conversions of
// std::basic_string<std::byte>, but complex enough that the call may
// convert the data to a text string on the libpqxx side. Which would be
// okay, except of course it's likely to be slower.
{
auto ptr{std::make_shared<std::basic_string<std::byte>>(
reinterpret_cast<std::byte const *>(raw_bytes), std::size(raw_bytes))};
auto rp{tx.exec_prepared1("EchoBin", ptr)};
auto pval{rp[0].as<std::basic_string<std::byte>>()};
PQXX_CHECK_EQUAL(
(std::string_view{
reinterpret_cast<char const *>(pval.c_str()), std::size(pval)}),
input, "Binary string as shared_ptr-to-optional went wrong.");
}
{
auto opt{std::optional<std::basic_string<std::byte>>{
std::in_place, reinterpret_cast<std::byte const *>(raw_bytes),
std::size(raw_bytes)}};
auto op{tx.exec_prepared1("EchoBin", opt)};
auto oval{op[0].as<std::basic_string<std::byte>>()};
PQXX_CHECK_EQUAL(
(std::string_view{
reinterpret_cast<char const *>(oval.c_str()), std::size(oval)}),
input, "Binary string as shared_ptr-to-optional went wrong.");
}
#if defined(PQXX_HAVE_CONCEPTS)
// By the way, it doesn't have to be a std::basic_string. Any contiguous
// range will do.
{
std::vector<std::byte> data{std::byte{'x'}, std::byte{'v'}};
auto op{tx.exec_prepared1("EchoBin", data)};
auto oval{op[0].as<std::basic_string<std::byte>>()};
PQXX_CHECK_EQUAL(
std::size(oval), 2u, "Binary data came back as wrong length.");
PQXX_CHECK_EQUAL(static_cast<int>(oval[0]), int('x'), "Wrong data.");
PQXX_CHECK_EQUAL(static_cast<int>(oval[1]), int('v'), "Wrong data.");
}
#endif
}
void test_params()
{
pqxx::connection c;
pqxx::work tx{c};
c.prepare("Concat2Numbers", "SELECT 10 * $1 + $2");
std::vector<int> values{3, 9};
pqxx::params params;
params.reserve(std::size(values));
params.append_multi(values);
auto const rw39{tx.exec_prepared1("Concat2Numbers", params)};
PQXX_CHECK_EQUAL(
rw39.front().as<int>(), 39,
"Dynamic prepared-statement parameters went wrong.");
c.prepare("Concat4Numbers", "SELECT 1000*$1 + 100*$2 + 10*$3 + $4");
auto const rw1396{tx.exec_prepared1("Concat4Numbers", 1, params, 6)};
PQXX_CHECK_EQUAL(
rw1396.front().as<int>(), 1396,
"Dynamic params did not interleave with static ones properly.");
}
void test_optional()
{
pqxx::connection c;
pqxx::work tx{c};
c.prepare("EchoNum", "SELECT $1::int");
pqxx::row rw{
tx.exec_prepared1("EchoNum", std::optional<int>{std::in_place, 10})};
PQXX_CHECK_EQUAL(
rw.front().as<int>(), 10,
"optional (with value) did not return the right value.");
rw = tx.exec_prepared1("EchoNum", std::optional<int>{});
PQXX_CHECK(
rw.front().is_null(), "optional without value did not come out as null.");
}
void test_prepared_statements()
{
test_registration_and_invocation();
test_basic_args();
test_multiple_params();
test_nulls();
test_strings();
test_binary();
test_params();
test_optional();
}
void test_placeholders_generates_names()
{
using pqxx::operator""_zv;
pqxx::placeholders name;
PQXX_CHECK_EQUAL(name.view(), "$1"_zv, "Bad placeholders initial zview.");
PQXX_CHECK_EQUAL(name.view(), "$1"sv, "Bad placeholders string_view.");
PQXX_CHECK_EQUAL(name.get(), "$1", "Bad placeholders::get().");
name.next();
PQXX_CHECK_EQUAL(name.view(), "$2"_zv, "Incorrect placeholders::next().");
name.next();
PQXX_CHECK_EQUAL(name.view(), "$3"_zv, "Incorrect placeholders::next().");
name.next();
PQXX_CHECK_EQUAL(name.view(), "$4"_zv, "Incorrect placeholders::next().");
name.next();
PQXX_CHECK_EQUAL(name.view(), "$5"_zv, "Incorrect placeholders::next().");
name.next();
PQXX_CHECK_EQUAL(name.view(), "$6"_zv, "Incorrect placeholders::next().");
name.next();
PQXX_CHECK_EQUAL(name.view(), "$7"_zv, "Incorrect placeholders::next().");
name.next();
PQXX_CHECK_EQUAL(name.view(), "$8"_zv, "Incorrect placeholders::next().");
name.next();
PQXX_CHECK_EQUAL(name.view(), "$9"_zv, "Incorrect placeholders::next().");
name.next();
PQXX_CHECK_EQUAL(name.view(), "$10"_zv, "Incorrect placeholders carry.");
name.next();
PQXX_CHECK_EQUAL(name.view(), "$11"_zv, "Incorrect placeholders 11.");
while (name.count() < 999) name.next();
PQXX_CHECK_EQUAL(name.view(), "$999"_zv, "Incorrect placeholders 999.");
name.next();
PQXX_CHECK_EQUAL(name.view(), "$1000"_zv, "Incorrect large placeholder.");
}
PQXX_REGISTER_TEST(test_prepared_statements);
PQXX_REGISTER_TEST(test_placeholders_generates_names);
} // namespace