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// file : libbrep/common.hxx -*- C++ -*-
// copyright : Copyright (c) 2014-2017 Code Synthesis Ltd
// license : MIT; see accompanying LICENSE file
#ifndef LIBBREP_COMMON_HXX
#define LIBBREP_COMMON_HXX
#include <ratio>
#include <chrono>
#include <type_traits> // static_assert
#include <libbrep/types.hxx>
#include <libbrep/utility.hxx>
// The uint16_t value range is not fully covered by SMALLINT PostgreSQL type
// to which uint16_t is mapped by default.
//
#pragma db value(uint16_t) type("INTEGER")
namespace brep
{
// Use an image type to map bpkg::version to the database since there
// is no way to modify individual components directly.
//
#pragma db value
struct _version
{
uint16_t epoch;
string canonical_upstream;
string canonical_release;
uint16_t revision;
string upstream;
optional<string> release;
};
}
#include <libbpkg/manifest.hxx>
namespace brep
{
using optional_version = optional<bpkg::version>;
using _optional_version = optional<_version>;
}
// Prevent assert() macro expansion in get/set expressions. This should
// appear after all #include directives since the assert() macro is
// redefined in each <assert.h> inclusion.
//
#ifdef ODB_COMPILER
# undef assert
# define assert assert
void assert (int);
#endif
// We have to keep these mappings at the global scope instead of inside
// the brep namespace because they need to be also effective in the
// bpkg namespace from which we "borrow" types (and some of them use version).
//
#pragma db map type(bpkg::version) as(brep::_version) \
to(brep::_version{(?).epoch, \
(?).canonical_upstream, \
(?).canonical_release, \
(?).revision, \
(?).upstream, \
(?).release}) \
from(bpkg::version ((?).epoch, \
std::move ((?).upstream), \
std::move ((?).release), \
(?).revision))
#pragma db map type(brep::optional_version) as(brep::_optional_version) \
to((?) \
? brep::_version{(?)->epoch, \
(?)->canonical_upstream, \
(?)->canonical_release, \
(?)->revision, \
(?)->upstream, \
(?)->release} \
: brep::_optional_version ()) \
from((?) \
? bpkg::version ((?)->epoch, \
std::move ((?)->upstream), \
std::move ((?)->release), \
(?)->revision) \
: brep::optional_version ())
namespace brep
{
// path
//
#pragma db map type(path) as(string) to((?).string ()) from(brep::path (?))
using optional_path = optional<path>;
using optional_string = optional<string>;
#pragma db map type(optional_path) as(brep::optional_string) \
to((?) ? (?)->string () : brep::optional_string ()) \
from((?) ? brep::path (*(?)) : brep::optional_path ())
#pragma db map type(dir_path) as(string) \
to((?).string ()) from(brep::dir_path (?))
// Ensure that timestamp can be represented in nonoseconds without loss of
// accuracy, so the following ODB mapping is adequate.
//
static_assert(
std::ratio_greater_equal<timestamp::period,
std::chrono::nanoseconds::period>::value,
"The following timestamp ODB mapping is invalid");
// As it pointed out in libbutl/timestamp.mxx we will overflow in year 2262,
// but by that time some larger basic type will be available for mapping.
//
#pragma db map type(timestamp) as(uint64_t) \
to(std::chrono::duration_cast<std::chrono::nanoseconds> ( \
(?).time_since_epoch ()).count ()) \
from(brep::timestamp ( \
std::chrono::duration_cast<brep::timestamp::duration> ( \
std::chrono::nanoseconds (?))))
// version
//
using bpkg::version;
#pragma db value
struct canonical_version
{
uint16_t epoch;
string canonical_upstream;
string canonical_release;
uint16_t revision;
bool
empty () const noexcept
{
// Note that an empty canonical_upstream doesn't denote an empty
// canonical_version. Remeber, that canonical_upstream doesn't include
// rightmost digit-only zero components? So non-empty version("0") has
// an empty canonical_upstream.
//
return epoch == 0 && canonical_upstream.empty () &&
canonical_release.empty () && revision == 0;
}
// Change collation to ensure the proper comparison of the "absent" release
// with a specified one.
//
// The default collation for UTF8-encoded TEXT columns in PostgreSQL is
// UCA-compliant. This makes the statement 'a' < '~' to be false, which
// in turn makes the statement 2.1.alpha < 2.1 to be false as well.
//
// Unicode Collation Algorithm (UCA): http://unicode.org/reports/tr10/
//
#pragma db member(canonical_release) options("COLLATE \"C\"")
};
#pragma db value transient
struct upstream_version: version
{
#pragma db member(upstream_) virtual(string) \
get(this.upstream) \
set(this = brep::version (0, std::move (?), std::string (), 0))
#pragma db member(release_) virtual(optional_string) \
get(this.release) \
set(this = brep::version ( \
0, std::move (this.upstream), std::move (?), 0))
upstream_version () = default;
upstream_version (version v): version (move (v)) {}
upstream_version&
operator= (version v) {version& b (*this); b = v; return *this;}
void
init (const canonical_version& cv, const upstream_version& uv)
{
*this = version (cv.epoch, uv.upstream, uv.release, cv.revision);
assert (cv.canonical_upstream == canonical_upstream &&
cv.canonical_release == canonical_release);
}
};
// Wildcard version. Satisfies any dependency constraint and is represented
// as 0+0 (which is also the "stub version"; since a real version is always
// greater than the stub version, we reuse it to signify a special case).
//
extern const version wildcard_version;
#pragma db value
struct package_id
{
string name;
canonical_version version;
package_id () = default;
package_id (string n, const brep::version& v)
: name (move (n)),
version {
v.epoch, v.canonical_upstream, v.canonical_release, v.revision}
{
}
};
// repository_type
//
using bpkg::repository_type;
// repository_url
//
using bpkg::repository_url;
// repository_location
//
using bpkg::repository_location;
#pragma db map type(repository_location) as(string) \
to((?).url ().string ()) \
from(brep::repository_location (brep::repository_url (?), \
brep::repository_type::bpkg))
// Version comparison operators.
//
// They allow comparing objects that have epoch, canonical_upstream,
// canonical_release, and revision data members. The idea is that this
// works for both query members of types version and canonical_version
// as well as for comparing canonical_version to version.
//
template <typename T1, typename T2>
inline auto
compare_version_eq (const T1& x, const T2& y, bool revision)
-> decltype (x.epoch == y.epoch)
{
// Since we don't quite know what T1 and T2 are (and where the resulting
// expression will run), let's not push our luck with something like
// (!revision || x.revision == y.revision).
//
auto r (x.epoch == y.epoch &&
x.canonical_upstream == y.canonical_upstream &&
x.canonical_release == y.canonical_release);
return revision
? r && x.revision == y.revision
: r;
}
template <typename T1, typename T2>
inline auto
compare_version_ne (const T1& x, const T2& y, bool revision)
-> decltype (x.epoch == y.epoch)
{
auto r (x.epoch != y.epoch ||
x.canonical_upstream != y.canonical_upstream ||
x.canonical_release != y.canonical_release);
return revision
? r || x.revision != y.revision
: r;
}
template <typename T1, typename T2>
inline auto
compare_version_lt (const T1& x, const T2& y, bool revision)
-> decltype (x.epoch == y.epoch)
{
auto r (
x.epoch < y.epoch ||
(x.epoch == y.epoch && x.canonical_upstream < y.canonical_upstream) ||
(x.epoch == y.epoch && x.canonical_upstream == y.canonical_upstream &&
x.canonical_release < y.canonical_release));
return revision
? r ||
(x.epoch == y.epoch && x.canonical_upstream == y.canonical_upstream &&
x.canonical_release == y.canonical_release && x.revision < y.revision)
: r;
}
template <typename T1, typename T2>
inline auto
compare_version_le (const T1& x, const T2& y, bool revision)
-> decltype (x.epoch == y.epoch)
{
auto r (
x.epoch < y.epoch ||
(x.epoch == y.epoch && x.canonical_upstream < y.canonical_upstream));
return revision
? r ||
(x.epoch == y.epoch && x.canonical_upstream == y.canonical_upstream &&
x.canonical_release < y.canonical_release) ||
(x.epoch == y.epoch && x.canonical_upstream == y.canonical_upstream &&
x.canonical_release == y.canonical_release && x.revision <= y.revision)
: r ||
(x.epoch == y.epoch && x.canonical_upstream == y.canonical_upstream &&
x.canonical_release <= y.canonical_release);
}
template <typename T1, typename T2>
inline auto
compare_version_gt (const T1& x, const T2& y, bool revision)
-> decltype (x.epoch == y.epoch)
{
auto r (
x.epoch > y.epoch ||
(x.epoch == y.epoch && x.canonical_upstream > y.canonical_upstream) ||
(x.epoch == y.epoch && x.canonical_upstream == y.canonical_upstream &&
x.canonical_release > y.canonical_release));
return revision
? r ||
(x.epoch == y.epoch && x.canonical_upstream == y.canonical_upstream &&
x.canonical_release == y.canonical_release && x.revision > y.revision)
: r;
}
template <typename T1, typename T2>
inline auto
compare_version_ge (const T1& x, const T2& y, bool revision)
-> decltype (x.epoch == y.epoch)
{
auto r (
x.epoch > y.epoch ||
(x.epoch == y.epoch && x.canonical_upstream > y.canonical_upstream));
return revision
? r ||
(x.epoch == y.epoch && x.canonical_upstream == y.canonical_upstream &&
x.canonical_release > y.canonical_release) ||
(x.epoch == y.epoch && x.canonical_upstream == y.canonical_upstream &&
x.canonical_release == y.canonical_release && x.revision >= y.revision)
: r ||
(x.epoch == y.epoch && x.canonical_upstream == y.canonical_upstream &&
x.canonical_release >= y.canonical_release);
}
template <typename T>
inline auto
order_by_version_desc (
const T& x,
bool first = true) -> //decltype ("ORDER BY" + x.epoch)
decltype (x.epoch == 0)
{
return (first ? "ORDER BY" : ", ")
+ x.epoch + "DESC,"
+ x.canonical_upstream + "DESC,"
+ x.canonical_release + "DESC,"
+ x.revision + "DESC";
}
// Package id comparison operators.
//
inline bool
operator< (const package_id& x, const package_id& y)
{
if (int r = x.name.compare (y.name))
return r < 0;
return compare_version_lt (x.version, y.version, true);
}
// They allow comparing objects that have name and version data members. The
// idea is that this works for both query members of package id types (in
// particular in join conditions) as well as for values of package_id type.
//
template <typename T1, typename T2>
inline auto
operator== (const T1& x, const T2& y)
-> decltype (x.name == y.name && x.version.epoch == y.version.epoch)
{
return x.name == y.name && compare_version_eq (x.version, y.version, true);
}
template <typename T1, typename T2>
inline auto
operator!= (const T1& x, const T2& y)
-> decltype (x.name == y.name && x.version.epoch == y.version.epoch)
{
return x.name != y.name || compare_version_ne (x.version, y.version, true);
}
}
#endif // LIBBREP_COMMON_HXX
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