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/** Implementation of libpqxx STL-style cursor classes.
*
* These classes wrap SQL cursors in STL-like interfaces.
*
* Copyright (c) 2000-2019, Jeroen T. Vermeulen.
*
* See COPYING for copyright license. If you did not receive a file called
* COPYING with this source code, please notify the distributor of this mistake,
* or contact the author.
*/
#include "pqxx/compiler-internal.hxx"
#include <iterator>
#include "pqxx/cursor"
#include "pqxx/internal/encodings.hxx"
#include "pqxx/internal/gates/connection-sql_cursor.hxx"
#include "pqxx/internal/gates/transaction-sql_cursor.hxx"
using namespace pqxx;
using namespace pqxx::internal;
namespace
{
/// Is this character a "useless trailing character" in a query?
/** A character is "useless" at the end of a query if it is either whitespace or
* a semicolon.
*/
inline bool useless_trail(char c)
{
return isspace(c) or c==';';
}
/// Find end of nonempty query, stripping off any trailing semicolon.
/** When executing a normal query, a trailing semicolon is meaningless but
* won't hurt. That's why we can't rule out that some code may include one.
*
* But for cursor queries, a trailing semicolon is a problem. The query gets
* embedded in a larger statement, which a semicolon would break into two.
* We'll have to remove it if present.
*
* A trailing semicolon may not actually be at the end. It could be masked by
* subsequent whitespace. If there's also a comment though, that's the
* caller's own lookout. We can't guard against every possible mistake, and
* text processing is actually remarkably sensitive to mistakes in a
* multi-encoding world.
*
* If there is a trailing semicolon, this function returns its offset. If
* there are more than one, it returns the offset of the first one. If there
* is no trailing semicolon, it returns the length of the query string.
*
* The query must be nonempty.
*/
std::string::size_type find_query_end(
const std::string &query,
encoding_group enc)
{
const auto text = query.c_str();
const auto size = query.size();
std::string::size_type end;
if (enc == encoding_group::MONOBYTE)
{
// This is an encoding where we can scan backwards from the end.
for (end = query.size(); end > 0 and useless_trail(text[end-1]); --end);
}
else
{
// Complex encoding. We only know how to iterate forwards, so start from
// the beginning.
end = 0;
pqxx::internal::for_glyphs(
enc,
[text, &end](const char *gbegin, const char *gend)
{
if (gend - gbegin > 1 or not useless_trail(*gbegin))
end = std::string::size_type(gend - text);
},
text, size);
}
return end;
}
} // namespace
pqxx::internal::sql_cursor::sql_cursor(
transaction_base &t,
const std::string &query,
const std::string &cname,
cursor_base::accesspolicy ap,
cursor_base::updatepolicy up,
cursor_base::ownershippolicy op,
bool hold,
result_format format) :
cursor_base{t.conn(), cname},
m_home{t.conn()},
m_adopted{false},
m_at_end{-1},
m_pos{0}
{
if (&t.conn() != &m_home) throw internal_error{"Cursor in wrong connection"};
#include "pqxx/internal/ignore-deprecated-pre.hxx"
m_home.activate();
#include "pqxx/internal/ignore-deprecated-post.hxx"
if (query.empty()) throw usage_error{"Cursor has empty query."};
const auto enc = enc_group(t.conn().encoding_id());
const auto qend = find_query_end(query, enc);
if (qend == 0) throw usage_error{"Cursor has effectively empty query."};
std::stringstream cq, qn;
cq << "DECLARE " << t.quote_name(name()) << " ";
if (format == result_format::binary) {
cq << "BINARY ";
}
if (ap == cursor_base::forward_only) cq << "NO ";
cq << "SCROLL ";
cq << "CURSOR ";
if (hold) cq << "WITH HOLD ";
cq << "FOR ";
cq.write(query.c_str(), std::streamsize(qend));
cq << ' ';
if (up != cursor_base::update) cq << "FOR READ ONLY ";
else cq << "FOR UPDATE ";
qn << "[DECLARE " << name() << ']';
t.exec(cq, qn.str());
// Now that we're here in the starting position, keep a copy of an empty
// result. That may come in handy later, because we may not be able to
// construct an empty result with all the right metadata due to the weird
// meaning of "FETCH 0."
init_empty_result(t);
// If we're creating a WITH HOLD cursor, noone is going to destroy it until
// after this transaction. That means the connection cannot be deactivated
// without losing the cursor.
if (hold)
gate::connection_sql_cursor{t.conn()}.add_reactivation_avoidance_count(1);
m_ownership = op;
}
pqxx::internal::sql_cursor::sql_cursor(
transaction_base &t,
const std::string &cname,
cursor_base::ownershippolicy op) :
cursor_base{t.conn(), cname, false},
m_home{t.conn()},
m_empty_result{},
m_adopted{true},
m_at_end{0},
m_pos{-1}
{
// If we take responsibility for destroying the cursor, that's one less
// reason not to allow the connection to be deactivated and reactivated.
// TODO: Go over lifetime/reactivation rules again to be sure they work.
if (op==cursor_base::owned)
gate::connection_sql_cursor{t.conn()}.add_reactivation_avoidance_count(-1);
m_adopted = true;
m_ownership = op;
}
void pqxx::internal::sql_cursor::close() noexcept
{
if (m_ownership==cursor_base::owned)
{
try
{
gate::connection_sql_cursor{m_home}.exec(
("CLOSE " + m_home.quote_name(name())).c_str(),
0);
}
catch (const std::exception &)
{
}
if (m_adopted)
gate::connection_sql_cursor{m_home}.add_reactivation_avoidance_count(-1);
m_ownership = cursor_base::loose;
}
}
void pqxx::internal::sql_cursor::init_empty_result(transaction_base &t)
{
if (pos() != 0) throw internal_error{"init_empty_result() from bad pos()."};
m_empty_result = t.exec("FETCH 0 IN " + m_home.quote_name(name()));
}
/// Compute actual displacement based on requested and reported displacements.
internal::sql_cursor::difference_type
pqxx::internal::sql_cursor::adjust(difference_type hoped,
difference_type actual)
{
if (actual < 0) throw internal_error{"Negative rows in cursor movement."};
if (hoped == 0) return 0;
const int direction = ((hoped < 0) ? -1 : 1);
bool hit_end = false;
if (actual != labs(hoped))
{
if (actual > labs(hoped))
throw internal_error{"Cursor displacement larger than requested."};
// If we see fewer rows than requested, then we've hit an end (on either
// side) of the result set. Wether we make an extra step to a one-past-end
// position or whether we're already there depends on where we were
// previously: if our last move was in the same direction and also fell
// short, we're already at a one-past-end row.
if (m_at_end != direction) ++actual;
// If we hit the beginning, make sure our position calculation ends up
// at zero (even if we didn't previously know where we were!), and if we
// hit the other end, register the fact that we now know where the end
// of the result set is.
if (direction > 0) hit_end = true;
else if (m_pos == -1) m_pos = actual;
else if (m_pos != actual)
throw internal_error{
"Moved back to beginning, but wrong position: "
"hoped=" + to_string(hoped) + ", "
"actual=" + to_string(actual) + ", "
"m_pos=" + to_string(m_pos) + ", "
"direction=" + to_string(direction) + "."};
m_at_end = direction;
}
else
{
m_at_end = 0;
}
if (m_pos >= 0) m_pos += direction*actual;
if (hit_end)
{
if (m_endpos >= 0 and m_pos != m_endpos)
throw internal_error{"Inconsistent cursor end positions."};
m_endpos = m_pos;
}
return direction*actual;
}
result pqxx::internal::sql_cursor::fetch(
difference_type rows,
difference_type &displacement)
{
if (rows == 0)
{
displacement = 0;
return m_empty_result;
}
const std::string query =
"FETCH " + stridestring(rows) + " IN " + m_home.quote_name(name());
const result r{gate::connection_sql_cursor{m_home}.exec(query.c_str(), 0)};
displacement = adjust(rows, difference_type(r.size()));
return r;
}
cursor_base::difference_type pqxx::internal::sql_cursor::move(
difference_type rows,
difference_type &displacement)
{
if (rows == 0)
{
displacement = 0;
return 0;
}
const std::string query =
"MOVE " + stridestring(rows) + " IN " + m_home.quote_name(name());
const result r(gate::connection_sql_cursor{m_home}.exec(query.c_str(), 0));
difference_type d = difference_type(r.affected_rows());
displacement = adjust(rows, d);
return d;
}
std::string pqxx::internal::sql_cursor::stridestring(difference_type n)
{
/* Some special-casing for ALL and BACKWARD ALL here. We used to use numeric
* "infinities" for difference_type for this (the highest and lowest possible
* values for "long"), but for PostgreSQL 8.0 at least, the backend appears to
* expect a 32-bit number and fails to parse large 64-bit numbers.
* We could change the alias to match this behaviour, but that would break
* if/when Postgres is changed to accept 64-bit displacements.
*/
static const std::string All{"ALL"}, BackAll{"BACKWARD ALL"};
if (n >= cursor_base::all()) return All;
else if (n <= cursor_base::backward_all()) return BackAll;
return to_string(n);
}
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