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// file : bpkg/rep-info.cxx -*- C++ -*-
// copyright : Copyright (c) 2014-2018 Code Synthesis Ltd
// license : MIT; see accompanying LICENSE file
#include <bpkg/rep-info.hxx>
#include <iostream> // cout
#include <algorithm> // find_if()
#include <libbutl/sha256.mxx> // sha256_to_fingerprint()
#include <libbutl/manifest-serializer.mxx>
#include <libbpkg/manifest.hxx>
#include <bpkg/auth.hxx>
#include <bpkg/package.hxx>
#include <bpkg/diagnostics.hxx>
#include <bpkg/manifest-utility.hxx>
#include <bpkg/rep-fetch.hxx>
using namespace std;
using namespace butl;
namespace bpkg
{
int
rep_info (const rep_info_options& o, cli::scanner& args)
{
tracer trace ("rep_info");
if (!args.more ())
fail << "repository location argument expected" <<
info << "run 'bpkg help rep-info' for more information";
repository_location rl (
parse_location (args.next (),
o.type_specified ()
? optional<repository_type> (o.type ())
: nullopt));
// Fetch everything we will need before printing anything. Ignore
// unknown manifest entries unless we are dumping them.
//
dir_path d (o.directory ());
rep_fetch_data rfd (
rep_fetch (o,
o.directory_specified () && d.empty () ? nullptr : &d,
rl,
!o.manifest () /* ignore_unknow */));
// Now print.
//
bool cert_info (o.cert_fingerprint () ||
o.cert_name () ||
o.cert_organization () ||
o.cert_email ());
bool all (!o.name () &&
!o.repositories () &&
!o.packages () &&
!cert_info);
try
{
cout.exceptions (ostream::badbit | ostream::failbit);
if (all || o.name ())
cout << rl.canonical_name () << " " << rl << endl;
// Certificate.
//
if (all || cert_info)
{
shared_ptr<const certificate>& cert (rfd.certificate);
const optional<string>& cert_pem (rfd.certificate_pem);
if (cert_pem)
{
// Repository is signed. If we got the repository certificate as the
// result of authentication then use it for printing as well.
// Otherwise parse it's PEM representation.
//
if (cert == nullptr)
cert = parse_certificate (o, *cert_pem, rl);
else
assert (!cert->dummy ());
}
else if (cert != nullptr)
{
// Reset the dummy certificate pointer that we got as a result of
// the unsigned repository authentication.
//
assert (cert->dummy ());
cert = nullptr;
}
if (all)
{
// Print in the human-friendly format (nothing for an unsigned
// repository).
//
if (cert != nullptr)
cout << "CN=" << cert->name << "/O=" << cert->organization <<
"/" << cert->email << endl
<< cert->fingerprint << endl;
}
else
{
// Print in the structured format if any of --cert-* options are
// specified. Print empty lines for an unsigned repository.
//
if (o.cert_fingerprint ())
{
if (cert != nullptr)
cout << cert->fingerprint;
cout << endl;
}
if (o.cert_name ())
{
if (cert != nullptr)
cout << "name:" << cert->name;
cout << endl;
}
if (o.cert_organization ())
{
if (cert != nullptr)
cout << cert->organization;
cout << endl;
}
if (o.cert_email ())
{
if (cert != nullptr)
cout << cert->email;
cout << endl;
}
}
}
// Repositories.
//
if (all || o.repositories ())
{
if (o.manifest ())
{
// Merge repository manifest lists, adding the fragment value to
// prerequisite/complement repository manifests, and picking the
// latest base repository manifest.
//
vector<repository_manifest> rms;
for (rep_fetch_data::fragment& fr: rfd.fragments)
{
for (repository_manifest& rm: fr.repositories)
{
if (rm.effective_role () != repository_role::base)
{
if (!fr.id.empty ())
rm.fragment = fr.id;
rms.push_back (move (rm));
}
}
}
// Append the latest base repository manifest.
//
// Note that there must be at least one fragment.
//
assert (!rfd.fragments.empty ());
rms.push_back (
find_base_repository (rfd.fragments.back ().repositories));
// Note: serializing without any extra repository_manifests info.
//
manifest_serializer s (cout, "stdout");
for (const repository_manifest& rm: rms)
rm.serialize (s);
s.next ("", ""); // End of stream.
}
else
{
// Merge complements/prerequisites from all fragments "upgrading"
// prerequisites to complements and preferring locations from the
// latest fragments.
//
vector<repository_manifest> rms;
for (rep_fetch_data::fragment& fr: rfd.fragments)
{
for (repository_manifest& rm: fr.repositories)
{
if (rm.effective_role () == repository_role::base)
continue;
repository_location l (rm.location, rl); // Complete.
auto i (find_if (rms.begin (), rms.end (),
[&l] (const repository_manifest& i)
{
return i.location.canonical_name () ==
l.canonical_name ();
}));
if (i == rms.end ())
{
rm.location = move (l);
rms.push_back (move (rm));
}
else
{
if (rm.effective_role () == repository_role::complement)
i->role = rm.effective_role ();
i->location = move (l);
}
}
}
for (const repository_manifest& rm: rms)
{
repository_role rr (rm.effective_role ());
const repository_location& l (rm.location);
const string& n (l.canonical_name ());
switch (rr)
{
case repository_role::complement:
cout << "complement " << n << " " << l << endl;
break;
case repository_role::prerequisite:
cout << "prerequisite " << n << " " << l << endl;
break;
case repository_role::base:
assert (false);
}
}
}
}
// Packages.
//
if (all || o.packages ())
{
if (o.manifest ())
{
// Merge package manifest lists, adding the fragment.
//
vector<package_manifest> pms;
for (rep_fetch_data::fragment& fr: rfd.fragments)
{
for (package_manifest& pm: fr.packages)
{
if (!fr.id.empty ())
pm.fragment = fr.id;
pms.push_back (move (pm));
}
}
// Note: serializing without any extra package_manifests info.
//
manifest_serializer s (cout, "stdout");
for (const package_manifest& pm: pms)
pm.serialize (s);
s.next ("", ""); // End of stream.
}
else
{
// Merge packages from all the fragments.
//
vector<package_manifest> pms;
for (rep_fetch_data::fragment& fr: rfd.fragments)
{
for (package_manifest& pm: fr.packages)
{
auto i (find_if (pms.begin (), pms.end (),
[&pm] (const package_manifest& i)
{
return i.name == pm.name &&
i.version == pm.version;
}));
if (i == pms.end ())
pms.push_back (move (pm));
}
}
// Separate package list from the general repository info.
//
cout << endl;
for (const package_manifest& pm: pms)
cout << pm.name << "/" << pm.version << endl;
}
}
}
catch (const manifest_serialization& e)
{
fail << "unable to serialize manifest: " << e.description;
}
catch (const io_error&)
{
fail << "unable to write to stdout";
}
return 0;
}
}
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