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|
// file : libbuild2/context.cxx -*- C++ -*-
// copyright : Copyright (c) 2014-2019 Code Synthesis Ltd
// license : MIT; see accompanying LICENSE file
#include <libbuild2/context.hxx>
#include <sstream>
#include <exception> // uncaught_exception[s]()
#include <libbuild2/rule.hxx>
#include <libbuild2/scope.hxx>
#include <libbuild2/target.hxx>
#include <libbuild2/diagnostics.hxx>
#include <libbutl/ft/exception.hxx> // uncaught_exceptions
// For command line variable parsing.
//
#include <libbuild2/token.hxx>
#include <libbuild2/lexer.hxx>
#include <libbuild2/parser.hxx>
using namespace std;
using namespace butl;
namespace build2
{
scheduler sched;
run_phase phase;
run_phase_mutex phase_mutex;
size_t load_generation;
bool run_phase_mutex::
lock (run_phase p)
{
bool r;
{
mlock l (m_);
bool u (lc_ == 0 && mc_ == 0 && ec_ == 0); // Unlocked.
// Increment the counter.
//
condition_variable* v (nullptr);
switch (p)
{
case run_phase::load: lc_++; v = &lv_; break;
case run_phase::match: mc_++; v = &mv_; break;
case run_phase::execute: ec_++; v = &ev_; break;
}
// If unlocked, switch directly to the new phase. Otherwise wait for the
// phase switch. Note that in the unlocked case we don't need to notify
// since there is nobody waiting (all counters are zero).
//
if (u)
{
phase = p;
r = !fail_;
}
else if (phase != p)
{
sched.deactivate (false /* external */);
for (; phase != p; v->wait (l)) ;
r = !fail_;
l.unlock (); // Important: activate() can block.
sched.activate (false /* external */);
}
else
r = !fail_;
}
// In case of load, acquire the exclusive access mutex.
//
if (p == run_phase::load)
{
lm_.lock ();
r = !fail_; // Re-query.
}
return r;
}
void run_phase_mutex::
unlock (run_phase p)
{
// In case of load, release the exclusive access mutex.
//
if (p == run_phase::load)
lm_.unlock ();
{
mlock l (m_);
// Decrement the counter and see if this phase has become unlocked.
//
bool u (false);
switch (p)
{
case run_phase::load: u = (--lc_ == 0); break;
case run_phase::match: u = (--mc_ == 0); break;
case run_phase::execute: u = (--ec_ == 0); break;
}
// If the phase is unlocked, pick a new phase and notify the waiters.
// Note that we notify all load waiters so that they can all serialize
// behind the second-level mutex.
//
if (u)
{
condition_variable* v;
if (lc_ != 0) {phase = run_phase::load; v = &lv_;}
else if (mc_ != 0) {phase = run_phase::match; v = &mv_;}
else if (ec_ != 0) {phase = run_phase::execute; v = &ev_;}
else {phase = run_phase::load; v = nullptr;}
if (v != nullptr)
{
l.unlock ();
v->notify_all ();
}
}
}
}
bool run_phase_mutex::
relock (run_phase o, run_phase n)
{
// Pretty much a fused unlock/lock implementation except that we always
// switch into the new phase.
//
assert (o != n);
bool r;
if (o == run_phase::load)
lm_.unlock ();
{
mlock l (m_);
bool u (false);
switch (o)
{
case run_phase::load: u = (--lc_ == 0); break;
case run_phase::match: u = (--mc_ == 0); break;
case run_phase::execute: u = (--ec_ == 0); break;
}
// Set if will be waiting or notifying others.
//
condition_variable* v (nullptr);
switch (n)
{
case run_phase::load: v = lc_++ != 0 || !u ? &lv_ : nullptr; break;
case run_phase::match: v = mc_++ != 0 || !u ? &mv_ : nullptr; break;
case run_phase::execute: v = ec_++ != 0 || !u ? &ev_ : nullptr; break;
}
if (u)
{
phase = n;
r = !fail_;
// Notify others that could be waiting for this phase.
//
if (v != nullptr)
{
l.unlock ();
v->notify_all ();
}
}
else // phase != n
{
sched.deactivate (false /* external */);
for (; phase != n; v->wait (l)) ;
r = !fail_;
l.unlock (); // Important: activate() can block.
sched.activate (false /* external */);
}
}
if (n == run_phase::load)
{
lm_.lock ();
r = !fail_; // Re-query.
}
return r;
}
// C++17 deprecated uncaught_exception() so use uncaught_exceptions() if
// available.
//
static inline bool
uncaught_exception ()
{
#ifdef __cpp_lib_uncaught_exceptions
return std::uncaught_exceptions () != 0;
#else
return std::uncaught_exception ();
#endif
}
// phase_lock
//
static
#ifdef __cpp_thread_local
thread_local
#else
__thread
#endif
phase_lock* phase_lock_instance;
phase_lock::
phase_lock (run_phase p)
: p (p)
{
if (phase_lock* l = phase_lock_instance)
assert (l->p == p);
else
{
if (!phase_mutex.lock (p))
{
phase_mutex.unlock (p);
throw failed ();
}
phase_lock_instance = this;
//text << this_thread::get_id () << " phase acquire " << p;
}
}
phase_lock::
~phase_lock ()
{
if (phase_lock_instance == this)
{
phase_lock_instance = nullptr;
phase_mutex.unlock (p);
//text << this_thread::get_id () << " phase release " << p;
}
}
// phase_unlock
//
phase_unlock::
phase_unlock (bool u)
: l (u ? phase_lock_instance : nullptr)
{
if (u)
{
phase_lock_instance = nullptr;
phase_mutex.unlock (l->p);
//text << this_thread::get_id () << " phase unlock " << l->p;
}
}
phase_unlock::
~phase_unlock () noexcept (false)
{
if (l != nullptr)
{
bool r (phase_mutex.lock (l->p));
phase_lock_instance = l;
// Fail unless we are already failing. Note that we keep the phase
// locked since there will be phase_lock down the stack to unlock it.
//
if (!r && !uncaught_exception ())
throw failed ();
//text << this_thread::get_id () << " phase lock " << l->p;
}
}
// phase_switch
//
phase_switch::
phase_switch (run_phase n)
: o (phase), n (n)
{
if (!phase_mutex.relock (o, n))
{
phase_mutex.relock (n, o);
throw failed ();
}
phase_lock_instance->p = n;
if (n == run_phase::load) // Note: load lock is exclusive.
load_generation++;
//text << this_thread::get_id () << " phase switch " << o << " " << n;
}
phase_switch::
~phase_switch () noexcept (false)
{
// If we are coming off a failed load phase, mark the phase_mutex as
// failed to terminate all other threads since the build state may no
// longer be valid.
//
if (n == run_phase::load && uncaught_exception ())
{
mlock l (phase_mutex.m_);
phase_mutex.fail_ = true;
}
bool r (phase_mutex.relock (n, o));
phase_lock_instance->p = o;
// Similar logic to ~phase_unlock().
//
if (!r && !uncaught_exception ())
throw failed ();
//text << this_thread::get_id () << " phase restore " << n << " " << o;
}
string current_mname;
string current_oname;
const meta_operation_info* current_mif;
const operation_info* current_inner_oif;
const operation_info* current_outer_oif;
size_t current_on;
execution_mode current_mode;
bool current_diag_noise;
atomic_count dependency_count;
atomic_count target_count;
atomic_count skip_count;
bool keep_going = false;
bool dry_run = false;
variable_overrides
reset (const strings& cmd_vars)
{
tracer trace ("reset");
// @@ Do we want to unload dynamically loaded modules? Note that this will
// be purely an optimization since a module could be linked-in (i.e., a
// module cannot expect to be unloaded/re-initialized for each meta-
// operation).
l6 ([&]{trace << "resetting build state";});
auto& vp (variable_pool::instance);
auto& sm (scope_map::instance);
variable_overrides vos;
targets.clear ();
sm.clear ();
vp.clear ();
// Reset meta/operation tables. Note that the order should match the id
// constants in <libbuild2/operation.hxx>.
//
meta_operation_table.clear ();
meta_operation_table.insert ("noop");
meta_operation_table.insert ("perform");
meta_operation_table.insert ("configure");
meta_operation_table.insert ("disfigure");
if (config_preprocess_create != nullptr)
meta_operation_table.insert (
meta_operation_data ("create", config_preprocess_create));
meta_operation_table.insert ("dist");
meta_operation_table.insert ("info");
operation_table.clear ();
operation_table.insert ("default");
operation_table.insert ("update");
operation_table.insert ("clean");
operation_table.insert ("test");
operation_table.insert ("update-for-test");
operation_table.insert ("install");
operation_table.insert ("uninstall");
operation_table.insert ("update-for-install");
// Create global scope. Note that the empty path is a prefix for any other
// path. See the comment in <libbutl/prefix-map.mxx> for details.
//
auto make_global_scope = [] () -> scope&
{
auto i (scope_map::instance.insert (dir_path ()));
scope& r (i->second);
r.out_path_ = &i->first;
global_scope = scope::global_ = &r;
return r;
};
scope& gs (make_global_scope ());
// Setup the global scope before parsing any variable overrides since they
// may reference these things.
//
gs.assign<dir_path> ("build.work") = work;
gs.assign<dir_path> ("build.home") = home;
// Build system driver process path.
//
gs.assign<process_path> ("build.path") =
process_path (nullptr, // Will be filled by value assignment.
path (argv0.recall_string ()),
path (argv0.effect));
// Build system verbosity level.
//
gs.assign<uint64_t> ("build.verbosity") = verb;
// Build system version (similar to what we do in the version module
// except here we don't include package epoch/revision).
//
{
const standard_version& v (build_version);
auto set = [&gs] (const char* var, auto val)
{
using T = decltype (val);
gs.assign (variable_pool::instance.insert<T> (var)) = move (val);
};
// Note: here we assume epoch will always be 1 and therefore omit the
// project_ prefix in a few places.
//
set ("build.version", v.string_project ());
set ("build.version.number", v.version);
set ("build.version.id", v.string_project_id ());
set ("build.version.major", uint64_t (v.major ()));
set ("build.version.minor", uint64_t (v.minor ()));
set ("build.version.patch", uint64_t (v.patch ()));
optional<uint16_t> a (v.alpha ());
optional<uint16_t> b (v.beta ());
set ("build.version.alpha", a.has_value ());
set ("build.version.beta", b.has_value ());
set ("build.version.pre_release", v.pre_release ().has_value ());
set ("build.version.pre_release_string", v.string_pre_release ());
set ("build.version.pre_release_number", uint64_t (a ? *a : b ? *b : 0));
set ("build.version.snapshot", v.snapshot ()); // bool
set ("build.version.snapshot_sn", v.snapshot_sn); // uint64
set ("build.version.snapshot_id", v.snapshot_id); // string
set ("build.version.snapshot_string", v.string_snapshot ());
// Build system interface version. In particular, it is embedded into
// build system modules as load_suffix.
//
set ("build.version.interface", build_version_interface);
// Allow detection (for example, in tests) whether this is a staged
// toolchain.
//
// Note that it is either staged or public, without queued, since we do
// not re-package things during the queued-to-public transition.
//
set ("build.version.stage", LIBBUILD2_STAGE);
}
// Enter the host information. Rather than jumping through hoops like
// config.guess, for now we are just going to use the compiler target we
// were built with. While it is not as precise (for example, a binary
// built for i686 might be running on x86_64), it is good enough of an
// approximation/fallback since most of the time we are interested in just
// the target class (e.g., linux, windows, macosx).
//
{
// Did the user ask us to use config.guess?
//
string orig (config_guess
? run<string> (3,
*config_guess,
[](string& l, bool) {return move (l);})
: BUILD2_HOST_TRIPLET);
l5 ([&]{trace << "original host: '" << orig << "'";});
try
{
target_triplet t (orig);
l5 ([&]{trace << "canonical host: '" << t.string () << "'; "
<< "class: " << t.class_;});
// Also enter as build.host.{cpu,vendor,system,version,class} for
// convenience of access.
//
gs.assign<string> ("build.host.cpu") = t.cpu;
gs.assign<string> ("build.host.vendor") = t.vendor;
gs.assign<string> ("build.host.system") = t.system;
gs.assign<string> ("build.host.version") = t.version;
gs.assign<string> ("build.host.class") = t.class_;
gs.assign<target_triplet> ("build.host") = move (t);
}
catch (const invalid_argument& e)
{
fail << "unable to parse build host '" << orig << "': " << e <<
info << "consider using the --config-guess option";
}
}
// Register builtin target types.
//
{
target_type_map& t (gs.target_types);
t.insert<file> ();
t.insert<alias> ();
t.insert<dir> ();
t.insert<fsdir> ();
t.insert<exe> ();
t.insert<doc> ();
t.insert<man> ();
t.insert<man1> ();
{
auto& tt (t.insert<manifest> ());
t.insert_file ("manifest", tt);
}
{
auto& tt (t.insert<buildfile> ());
t.insert_file ("buildfile", tt);
}
}
// Parse and enter the command line variables. We do it before entering
// any other variables so that all the variables that are overriden are
// marked as such first. Then, as we enter variables, we can verify that
// the override is alowed.
//
for (size_t i (0); i != cmd_vars.size (); ++i)
{
const string& s (cmd_vars[i]);
istringstream is (s);
is.exceptions (istringstream::failbit | istringstream::badbit);
// Similar to buildspec we do "effective escaping" and only for ['"\$(]
// (basically what's necessary inside a double-quoted literal plus the
// single quote).
//
lexer l (is, path ("<cmdline>"), 1 /* line */, "\'\"\\$(");
// At the buildfile level the scope-specific variable should be
// separated from the directory with a whitespace, for example:
//
// ./ foo=$bar
//
// However, requiring this for command line variables would be too
// inconvinient so we support both.
//
// We also have the optional visibility modifier as a first character of
// the variable name:
//
// ! - global
// % - project
// / - scope
//
// The last one clashes a bit with the directory prefix:
//
// ./ /foo=bar
// .//foo=bar
//
// But that's probably ok (the need for a scope-qualified override with
// scope visibility should be pretty rare). Note also that to set the
// value on the global scope we use !.
//
// And so the first token should be a word which can be either a
// variable name (potentially with the directory qualification) or just
// the directory, in which case it should be followed by another word
// (unqualified variable name).
//
token t (l.next ());
optional<dir_path> dir;
if (t.type == token_type::word)
{
string& v (t.value);
size_t p (path::traits_type::rfind_separator (v));
if (p != string::npos && p != 0) // If first then visibility.
{
if (p == v.size () - 1)
{
// Separate directory.
//
dir = dir_path (move (v));
t = l.next ();
// Target-specific overrides are not yet supported (and probably
// never will be; the beast is already complex enough).
//
if (t.type == token_type::colon)
fail << "'" << s << "' is a target-specific override" <<
info << "use double '--' to treat this argument as buildspec";
}
else
{
// Combined directory.
//
// If double separator (visibility marker), then keep the first in
// name.
//
if (p != 0 && path::traits_type::is_separator (v[p - 1]))
--p;
dir = dir_path (t.value, 0, p + 1); // Include the separator.
t.value.erase (0, p + 1); // Erase the separator.
}
if (dir->relative ())
{
// Handle the special relative to base scope case (.../).
//
auto i (dir->begin ());
if (*i == "...")
dir = dir_path (++i, dir->end ()); // Note: can become empty.
else
dir->complete (); // Relative to CWD.
}
if (dir->absolute ())
dir->normalize ();
}
}
token_type tt (l.next ().type);
// The token should be the variable name followed by =, +=, or =+.
//
if (t.type != token_type::word || t.value.empty () ||
(tt != token_type::assign &&
tt != token_type::prepend &&
tt != token_type::append))
{
fail << "expected variable assignment instead of '" << s << "'" <<
info << "use double '--' to treat this argument as buildspec";
}
// Take care of the visibility. Note that here we rely on the fact that
// none of these characters are lexer's name separators.
//
char c (t.value[0]);
if (path::traits_type::is_separator (c))
c = '/'; // Normalize.
string n (t.value, c == '!' || c == '%' || c == '/' ? 1 : 0);
if (c == '!' && dir)
fail << "scope-qualified global override of variable " << n;
variable& var (const_cast<variable&> (
vp.insert (n, true /* overridable */)));
const variable* o;
{
variable_visibility v (c == '/' ? variable_visibility::scope :
c == '%' ? variable_visibility::project :
variable_visibility::normal);
const char* k (tt == token_type::assign ? "__override" :
tt == token_type::append ? "__suffix" : "__prefix");
unique_ptr<variable> p (
new variable {
n + '.' + to_string (i + 1) + '.' + k,
nullptr /* aliases */,
nullptr /* type */,
nullptr /* overrides */,
v});
// Back link.
//
p->aliases = p.get ();
if (var.overrides != nullptr)
swap (p->aliases,
const_cast<variable*> (var.overrides.get ())->aliases);
// Forward link.
//
p->overrides = move (var.overrides);
var.overrides = move (p);
o = var.overrides.get ();
}
// Currently we expand project overrides in the global scope to keep
// things simple. Pass original variable for diagnostics. Use current
// working directory as pattern base.
//
parser p;
pair<value, token> r (p.parse_variable_value (l, gs, &work, var));
if (r.second.type != token_type::eos)
fail << "unexpected " << r.second << " in variable assignment "
<< "'" << s << "'";
// Make sure the value is not typed.
//
if (r.first.type != nullptr)
fail << "typed override of variable " << n;
// Global and absolute scope overrides we can enter directly. Project
// and relative scope ones will be entered by the caller for each
// amalgamation/project.
//
if (c == '!' || (dir && dir->absolute ()))
{
scope& s (c == '!' ? gs : sm.insert (*dir)->second);
auto p (s.vars.insert (*o));
assert (p.second); // Variable name is unique.
value& v (p.first);
v = move (r.first);
}
else
vos.push_back (
variable_override {var, *o, move (dir), move (r.first)});
}
// Enter builtin variables and patterns.
//
// All config. variables are by default overridable.
//
vp.insert_pattern ("config.**", nullopt, true, nullopt, true, false);
// file.cxx:import() (note that order is important; see insert_pattern()).
//
vp.insert_pattern<abs_dir_path> (
"config.import.*", true, variable_visibility::normal, true);
vp.insert_pattern<path> (
"config.import.**", true, variable_visibility::normal, true);
// module.cxx:load_module().
//
{
auto v_p (variable_visibility::project);
vp.insert_pattern<bool> ("**.booted", false, v_p);
vp.insert_pattern<bool> ("**.loaded", false, v_p);
vp.insert_pattern<bool> ("**.configured", false, v_p);
}
{
auto v_p (variable_visibility::project);
auto v_t (variable_visibility::target);
auto v_q (variable_visibility::prereq);
var_src_root = &vp.insert<dir_path> ("src_root");
var_out_root = &vp.insert<dir_path> ("out_root");
var_src_base = &vp.insert<dir_path> ("src_base");
var_out_base = &vp.insert<dir_path> ("out_base");
var_forwarded = &vp.insert<bool> ("forwarded", v_p);
// Note that subprojects is not typed since the value requires
// pre-processing (see file.cxx).
//
var_project = &vp.insert<project_name> ("project", v_p);
var_amalgamation = &vp.insert<dir_path> ("amalgamation", v_p);
var_subprojects = &vp.insert ("subprojects", v_p);
var_version = &vp.insert<string> ("version", v_p);
var_project_url = &vp.insert<string> ("project.url", v_p);
var_project_summary = &vp.insert<string> ("project.summary", v_p);
var_import_target = &vp.insert<name> ("import.target");
var_clean = &vp.insert<bool> ("clean", v_t);
var_backlink = &vp.insert<string> ("backlink", v_t);
var_include = &vp.insert<string> ("include", v_q);
vp.insert<string> (var_extension, v_t);
// Backlink executables and (generated) documentation by default.
//
gs.target_vars[exe::static_type]["*"].assign (var_backlink) = "true";
gs.target_vars[doc::static_type]["*"].assign (var_backlink) = "true";
var_build_meta_operation = &vp.insert<string> ("build.meta_operation");
}
// Register builtin rules.
//
{
rule_map& r (gs.rules); // Note: global scope!
//@@ outer
r.insert<alias> (perform_id, 0, "alias", alias_rule::instance);
r.insert<fsdir> (perform_update_id, "fsdir", fsdir_rule::instance);
r.insert<fsdir> (perform_clean_id, "fsdir", fsdir_rule::instance);
r.insert<mtime_target> (perform_update_id, "file", file_rule::instance);
r.insert<mtime_target> (perform_clean_id, "file", file_rule::instance);
}
return vos;
}
void (*config_save_variable) (scope&, const variable&, uint64_t);
const string& (*config_preprocess_create) (const variable_overrides&,
values&,
vector_view<opspec>&,
bool,
const location&);
const variable* var_src_root;
const variable* var_out_root;
const variable* var_src_base;
const variable* var_out_base;
const variable* var_forwarded;
const variable* var_project;
const variable* var_amalgamation;
const variable* var_subprojects;
const variable* var_version;
const variable* var_project_url;
const variable* var_project_summary;
const variable* var_import_target;
const variable* var_clean;
const variable* var_backlink;
const variable* var_include;
const char var_extension[10] = "extension";
const variable* var_build_meta_operation;
dir_path
src_out (const dir_path& out, const scope& r)
{
assert (r.root ());
return src_out (out, r.out_path (), r.src_path ());
}
dir_path
out_src (const dir_path& src, const scope& r)
{
assert (r.root ());
return out_src (src, r.out_path (), r.src_path ());
}
dir_path
src_out (const dir_path& o,
const dir_path& out_root, const dir_path& src_root)
{
assert (o.sub (out_root));
return src_root / o.leaf (out_root);
}
dir_path
out_src (const dir_path& s,
const dir_path& out_root, const dir_path& src_root)
{
assert (s.sub (src_root));
return out_root / s.leaf (src_root);
}
// diag_do(), etc.
//
string
diag_do (const action&)
{
const meta_operation_info& m (*current_mif);
const operation_info& io (*current_inner_oif);
const operation_info* oo (current_outer_oif);
string r;
// perform(update(x)) -> "update x"
// configure(update(x)) -> "configure updating x"
//
if (m.name_do.empty ())
r = io.name_do;
else
{
r = m.name_do;
if (io.name_doing[0] != '\0')
{
r += ' ';
r += io.name_doing;
}
}
if (oo != nullptr)
{
r += " (for ";
r += oo->name;
r += ')';
}
return r;
}
void
diag_do (ostream& os, const action& a, const target& t)
{
os << diag_do (a) << ' ' << t;
}
string
diag_doing (const action&)
{
const meta_operation_info& m (*current_mif);
const operation_info& io (*current_inner_oif);
const operation_info* oo (current_outer_oif);
string r;
// perform(update(x)) -> "updating x"
// configure(update(x)) -> "configuring updating x"
//
if (!m.name_doing.empty ())
r = m.name_doing;
if (io.name_doing[0] != '\0')
{
if (!r.empty ()) r += ' ';
r += io.name_doing;
}
if (oo != nullptr)
{
r += " (for ";
r += oo->name;
r += ')';
}
return r;
}
void
diag_doing (ostream& os, const action& a, const target& t)
{
os << diag_doing (a) << ' ' << t;
}
string
diag_did (const action&)
{
const meta_operation_info& m (*current_mif);
const operation_info& io (*current_inner_oif);
const operation_info* oo (current_outer_oif);
string r;
// perform(update(x)) -> "updated x"
// configure(update(x)) -> "configured updating x"
//
if (!m.name_did.empty ())
{
r = m.name_did;
if (io.name_doing[0] != '\0')
{
r += ' ';
r += io.name_doing;
}
}
else
r += io.name_did;
if (oo != nullptr)
{
r += " (for ";
r += oo->name;
r += ')';
}
return r;
}
void
diag_did (ostream& os, const action& a, const target& t)
{
os << diag_did (a) << ' ' << t;
}
void
diag_done (ostream& os, const action&, const target& t)
{
const meta_operation_info& m (*current_mif);
const operation_info& io (*current_inner_oif);
const operation_info* oo (current_outer_oif);
// perform(update(x)) -> "x is up to date"
// configure(update(x)) -> "updating x is configured"
//
if (m.name_done.empty ())
{
os << t;
if (io.name_done[0] != '\0')
os << ' ' << io.name_done;
if (oo != nullptr)
os << " (for " << oo->name << ')';
}
else
{
if (io.name_doing[0] != '\0')
os << io.name_doing << ' ';
if (oo != nullptr)
os << "(for " << oo->name << ") ";
os << t << ' ' << m.name_done;
}
}
}
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