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|
// file : libbuild2/scope.cxx -*- C++ -*-
// license : MIT; see accompanying LICENSE file
#include <libbuild2/scope.hxx>
#include <libbuild2/rule.hxx>
#include <libbuild2/target.hxx>
#include <libbuild2/context.hxx>
using namespace std;
namespace build2
{
ostream&
operator<< (ostream& os, const subprojects& sps)
{
for (auto b (sps.begin ()), i (b); os && i != sps.end (); ++i)
{
// See find_subprojects() for details.
//
const project_name& n (
path::traits_type::is_separator (i->first.string ().back ())
? empty_project_name
: i->first);
os << (i != b ? " " : "") << n << '@' << i->second.string ();
}
return os;
}
// scope
//
scope::
scope (context& c, bool shared)
: ctx (c), vars (c, shared), target_vars (c, shared)
{
}
scope::
~scope ()
{
// Definition of adhoc_rule_pattern.
}
pair<lookup, size_t> scope::
lookup_original (const variable& var,
const target_key* tk,
const target_key* g1k,
const target_key* g2k,
size_t start_d) const
{
assert (tk != nullptr || var.visibility != variable_visibility::target);
assert (g2k == nullptr || g1k != nullptr);
size_t d (0);
if (var.visibility == variable_visibility::prereq)
return make_pair (lookup_type (), d);
// Process target type/pattern-specific prepend/append values.
//
auto pre_app = [&var, this] (lookup_type& l,
const scope* s,
const target_key* tk,
const target_key* g1k,
const target_key* g2k,
string n)
{
const value& v (*l);
assert ((v.extra == 1 || v.extra == 2) && v.type == nullptr);
// First we need to look for the stem value starting from the "next
// lookup point". That is, if we have the group, then from the
// s->target_vars (for the group), otherwise from s->vars, and then
// continuing looking in the outer scopes (for both target and group).
// Note that this may have to be repeated recursively, i.e., we may have
// prepents/appends in outer scopes. Also, if the value is for the
// group, then we shouldn't be looking for stem in the target's
// variables. In other words, once we "jump" to group, we stay there.
//
lookup_type stem (s->lookup_original (var, tk, g1k, g2k, 2).first);
// Check the cache.
//
pair<value&, ulock> entry (
s->target_vars.cache.insert (
ctx,
make_tuple (&v, tk->type, !n.empty () ? move (n) : *tk->name),
stem,
static_cast<const variable_map::value_data&> (v).version,
var));
value& cv (entry.first);
// If cache miss/invalidation, update the value.
//
if (entry.second.owns_lock ())
{
// Un-typify the cache. This can be necessary, for example, if we are
// changing from one value-typed stem to another.
//
// Note: very similar logic as in the override cache population code
// below.
//
if (!stem.defined () || cv.type != stem->type)
{
cv = nullptr;
cv.type = nullptr; // Un-typify.
}
// Copy the stem.
//
if (stem.defined ())
cv = *stem;
// Typify the cache value in case there is no stem (we still want to
// prepend/append things in type-aware way).
//
if (cv.type == nullptr && var.type != nullptr)
typify (cv, *var.type, &var);
// Now prepend/append the value, unless it is NULL.
//
if (v)
{
if (v.extra == 1)
cv.prepend (names (cast<names> (v)), &var);
else
cv.append (names (cast<names> (v)), &var);
}
}
// Return cache as the resulting value but retain l.var/vars, so it
// looks as if the value came from s->target_vars.
//
l.value = &cv;
};
// Most of the time we match against the target name directly but
// sometimes we may need to match against the directory leaf (dir{} or
// fsdir{}) or incorporate the extension. We therefore try hard to avoid
// the copy.
//
optional<string> tn;
optional<string> g1n;
optional<string> g2n;
for (const scope* s (this); s != nullptr; )
{
if (tk != nullptr) // This started from the target.
{
bool f (!s->target_vars.empty ());
// Target.
//
if (++d >= start_d)
{
if (f)
{
lookup_type l (s->target_vars.find (*tk, var, tn));
if (l.defined ())
{
if (l->extra != 0) // Prepend/append?
pre_app (l, s, tk, g1k, g2k, move (*tn));
return make_pair (move (l), d);
}
}
}
// Group.
//
if (++d >= start_d)
{
if (f && g1k != nullptr)
{
lookup_type l (s->target_vars.find (*g1k, var, g1n));
if (l.defined ())
{
if (l->extra != 0) // Prepend/append?
pre_app (l, s, g1k, g2k, nullptr, move (*g1n));
return make_pair (move (l), d);
}
if (g2k != nullptr)
{
l = s->target_vars.find (*g2k, var, g2n);
if (l.defined ())
{
if (l->extra != 0) // Prepend/append?
pre_app (l, s, g2k, nullptr, nullptr, move (*g2n));
return make_pair (move (l), d);
}
}
}
}
}
// Note that we still increment the lookup depth so that we can compare
// depths of variables with different visibilities.
//
if (++d >= start_d && var.visibility != variable_visibility::target)
{
auto p (s->vars.lookup (var));
if (p.first != nullptr)
return make_pair (lookup_type (*p.first, p.second, s->vars), d);
}
switch (var.visibility)
{
case variable_visibility::scope:
s = nullptr;
break;
case variable_visibility::target:
case variable_visibility::project:
s = s->root () ? nullptr : s->parent_scope ();
break;
case variable_visibility::global:
s = s->parent_scope ();
break;
case variable_visibility::prereq:
assert (false);
}
}
return make_pair (lookup_type (), size_t (~0));
}
auto scope::
lookup_override_info (const variable& var,
const pair<lookup_type, size_t> original,
bool target,
bool rule) const -> override_info
{
assert (!rule || target); // Rule-specific is target-specific.
// Normally there would be no overrides and if there are, there will only
// be a few of them. As a result, here we concentrate on keeping the logic
// as straightforward as possible without trying to optimize anything.
//
// Note also that we rely (e.g., in the config module) on the fact that if
// no overrides apply, then we return the original value and not its copy
// in the cache (this is used to detect if the value was overriden).
//
assert (var.overrides != nullptr);
const lookup_type& orig (original.first);
size_t orig_depth (original.second);
// The first step is to find out where our cache will reside. After some
// meditation you will see it should be next to the innermost (scope-wise)
// value of this variable (override or original).
//
// We also keep track of the root scope of the project from which this
// innermost value comes. This is used to decide whether a non-recursive
// project-wise override applies. And also where our variable cache is.
//
const variable_map* inner_vars (nullptr);
const scope* inner_proj (nullptr);
// One special case is if the original is target/rule-specific, which is
// the most innermost. Or is it innermostest?
//
bool targetspec (false);
if (target)
{
targetspec = orig.defined () && (orig_depth == 1 ||
orig_depth == 2 ||
(rule && orig_depth == 3));
if (targetspec)
{
inner_vars = orig.vars;
inner_proj = root_scope ();
}
}
const scope* s;
// Return true if the override applies to a value from vars/proj. Note
// that it expects vars and proj to be not NULL; if there is nothing "more
// inner", then any override will still be "visible".
//
auto applies = [&s] (const variable* o,
const variable_map* vars,
const scope* proj) -> bool
{
switch (o->visibility)
{
case variable_visibility::scope:
{
// Does not apply if in a different scope.
//
if (vars != &s->vars)
return false;
break;
}
case variable_visibility::project:
{
// Does not apply if in a subproject.
//
// Note that before we used to require the same project but that
// missed values that are "visible" from the outer projects.
//
// If root scope is NULL, then we are looking at the global scope.
//
const scope* rs (s->root_scope ());
if (rs != nullptr && rs->sub_root (*proj))
return false;
break;
}
case variable_visibility::global:
break;
case variable_visibility::target:
case variable_visibility::prereq:
assert (false);
}
return true;
};
// Return the override value if present in scope s and (optionally) of
// the specified kind (__override, __prefix, etc).
//
auto lookup = [&s, &var] (const variable* o,
const char* k = nullptr) -> lookup_type
{
if (k != nullptr && !o->override (k))
return lookup_type ();
// Note: using the original as storage variable.
// Note: have to suppress aliases since used for something else.
//
return lookup_type (
s->vars.lookup (*o, true /* typed */, false /* aliased */).first,
&var,
&s->vars);
};
// Return true if a value is from this scope (either target type/pattern-
// specific or ordinary).
//
auto belongs = [&s, target] (const lookup_type& l) -> bool
{
if (target)
{
for (auto& p1: s->target_vars)
for (auto& p2: p1.second)
if (l.vars == &p2.second)
return true;
}
return l.vars == &s->vars;
};
// While looking for the cache we also detect if none of the overrides
// apply. In this case the result is simply the original value (if any).
//
bool apply (false);
for (s = this; s != nullptr; s = s->parent_scope ())
{
// If we are still looking for the cache, see if the original comes from
// this scope. We check this before the overrides since it can come from
// the target type/patter-specific variables, which is "more inner" than
// normal scope variables (see lookup_original()).
//
if (inner_vars == nullptr && orig.defined () && belongs (orig))
{
inner_vars = orig.vars;
inner_proj = s->root_scope ();
}
for (const variable* o (var.overrides.get ());
o != nullptr;
o = o->overrides.get ())
{
if (inner_vars != nullptr && !applies (o, inner_vars, inner_proj))
continue;
auto l (lookup (o));
if (l.defined ())
{
if (inner_vars == nullptr)
{
inner_vars = l.vars;
inner_proj = s->root_scope ();
}
apply = true;
break;
}
}
// We can stop if we found the cache and at least one override applies.
//
if (inner_vars != nullptr && apply)
break;
}
if (!apply)
return override_info {original, orig.defined ()};
assert (inner_vars != nullptr);
// If for some reason we are not in a project, use the cache from the
// global scope.
//
if (inner_proj == nullptr)
inner_proj = &ctx.global_scope;
// Now find our "stem", that is, the value to which we will be appending
// suffixes and prepending prefixes. This is either the original or the
// __override, provided it applies. We may also not have either.
//
lookup_type stem;
size_t stem_depth (0);
const scope* stem_proj (nullptr);
const variable* stem_ovr (nullptr); // __override if found and applies.
// Again the special case of a target/rule-specific variable.
//
if (targetspec)
{
stem = orig;
stem_depth = orig_depth;
stem_proj = root_scope ();
}
// Depth at which we found the override (with implied target/rule-specific
// lookup counts).
//
size_t ovr_depth (target ? (rule ? 3 : 2) : 0);
for (s = this; s != nullptr; s = s->parent_scope ())
{
bool done (false);
// First check if the original is from this scope.
//
if (orig.defined () && belongs (orig))
{
stem = orig;
stem_depth = orig_depth;
stem_proj = s->root_scope ();
// Keep searching.
}
++ovr_depth;
// Then look for an __override that applies.
//
// Note that the override list is in the reverse order of appearance and
// so we will naturally see the most recent override first.
//
for (const variable* o (var.overrides.get ());
o != nullptr;
o = o->overrides.get ())
{
// If we haven't yet found anything, then any override will still be
// "visible" even if it doesn't apply.
//
if (stem.defined () && !applies (o, stem.vars, stem_proj))
continue;
auto l (lookup (o, "__override"));
if (l.defined ())
{
stem = move (l);
stem_depth = ovr_depth;
stem_proj = s->root_scope ();
stem_ovr = o;
done = true;
break;
}
}
if (done)
break;
}
// Check the cache.
//
variable_override_cache& cache (
inner_proj == &ctx.global_scope
? ctx.global_override_cache
: inner_proj->root_extra->override_cache);
pair<value&, ulock> entry (
cache.insert (
ctx,
make_pair (&var, inner_vars),
stem,
0, // Overrides are immutable.
var));
value& cv (entry.first);
bool cl (entry.second.owns_lock ());
// If cache miss/invalidation, update the value.
//
if (cl)
{
// Note: very similar logic as in the target type/pattern specific cache
// population code above.
//
// Un-typify the cache. This can be necessary, for example, if we are
// changing from one value-typed stem to another.
//
if (!stem.defined () || cv.type != stem->type)
{
cv = nullptr;
cv.type = nullptr; // Un-typify.
}
if (stem.defined ())
cv = *stem;
// Typify the cache value. If the stem is the original, then the type
// would get propagated automatically. But the stem could also be the
// override, which is kept untyped. Or the stem might not be there at
// all while we still need to apply prefixes/suffixes in the type-aware
// way.
//
if (cv.type == nullptr && var.type != nullptr)
typify (cv, *var.type, &var);
}
// Now apply override prefixes and suffixes (if updating the cache). Also
// calculate the vars and depth of the result, which will be those of the
// stem or prefix/suffix that applies, whichever is the innermost.
//
// Note: we could probably cache this information instead of recalculating
// it every time.
//
size_t depth (stem_depth);
const variable_map* vars (stem.vars);
const scope* proj (stem_proj);
ovr_depth = target ? (rule ? 3 : 2) : 0;
for (s = this; s != nullptr; s = s->parent_scope ())
{
++ovr_depth;
// The override list is in the reverse order of appearance so we need to
// iterate backwards in order to apply things in the correct order.
//
// We also need to skip any append/prepend overrides that appear before
// __override (in the command line order), provided it is from this
// scope.
//
bool skip (stem_ovr != nullptr && stem_depth == ovr_depth);
for (const variable* o (var.overrides->aliases); // Last override.
o != nullptr;
o = (o->aliases != var.overrides->aliases ? o->aliases : nullptr))
{
if (skip)
{
if (stem_ovr == o) // Keep skipping until after we see __override.
skip = false;
continue;
}
// First see if this override applies. This is tricky: what if the
// stem is a "visible" override from an outer project? Shouldn't its
// overrides apply? Sure sounds logical. So we use the project of the
// stem's scope.
//
if (vars != nullptr && !applies (o, vars, proj))
continue;
// Note that we keep override values as untyped names even if the
// variable itself is typed. We also pass the original variable for
// diagnostics.
//
auto lp (lookup (o, "__prefix"));
auto ls (lookup (o, "__suffix"));
if (cl)
{
// Note: if we have both, then one is already in the stem.
//
if (lp) // No sense to prepend/append if NULL.
{
cv.prepend (names (cast<names> (lp)), &var);
}
else if (ls)
{
cv.append (names (cast<names> (ls)), &var);
}
}
if (lp.defined () || ls.defined ())
{
// If we had no stem, use the first override as a surrogate stem.
//
if (vars == nullptr)
{
depth = ovr_depth;
vars = &s->vars;
proj = s->root_scope ();
}
// Otherwise, pick the innermost location between the stem and
// prefix/suffix.
//
else if (ovr_depth < depth)
{
depth = ovr_depth;
vars = &s->vars;
}
}
}
}
// Use the location of the innermost value that contributed as the
// location of the result.
//
return override_info {
make_pair (lookup_type (&cv, &var, vars), depth),
orig.defined () && stem == orig};
}
value& scope::
append (const variable& var)
{
// Note that here we want the original value without any overrides
// applied.
//
auto l (lookup_original (var).first);
if (l.defined () && l.belongs (*this)) // Existing var in this scope.
return vars.modify (l); // Ok since this is original.
value& r (assign (var)); // NULL.
if (l.defined ())
r = *l; // Copy value (and type) from the outer scope.
return r;
}
const target_type* scope::
find_target_type (const string& tt) const
{
// Search the project's root scope then the global scope.
//
if (const scope* rs = root_scope ())
{
if (const target_type* r = rs->root_extra->target_types.find (tt))
return r;
}
return ctx.global_target_types.find (tt);
}
// Find target type from file name.
//
static const target_type*
find_target_type_file (const scope& s, const string& n)
{
// Pretty much the same logic as in find_target_type() above.
//
if (const scope* rs = s.root_scope ())
{
if (const target_type* r = rs->root_extra->target_types.find_file (n))
return r;
}
return s.ctx.global_target_types.find_file (n);
}
pair<const target_type*, optional<string>> scope::
find_target_type (name& n, const location& loc, const target_type* tt) const
{
optional<string> ext;
string& v (n.value);
// If the name is typed, resolve the target type it and bail out if not
// found. Otherwise, we know in the end it will resolve to something (if
// nothing else, either dir{} or file{}), so we can go ahead and process
// the name.
//
if (tt == nullptr)
{
if (n.typed ())
{
tt = find_target_type (n.type);
if (tt == nullptr)
return make_pair (tt, move (ext));
}
else
{
// Empty name as well as '.' and '..' signify a directory. Note that
// this logic must be consistent with other places (grep for "..").
//
if (v.empty () || v == "." || v == "..")
tt = &dir::static_type;
}
}
// Directories require special name processing. If we find that more
// targets deviate, then we should make this target type-specific.
//
if (tt != nullptr && (tt->is_a<dir> () || tt->is_a<fsdir> ()))
{
// The canonical representation of a directory name is with empty
// value.
//
if (!v.empty ())
{
n.dir /= dir_path (v); // Move name value to dir.
v.clear ();
}
}
else if (!v.empty ())
{
// Split the path into its directory part (if any) the name part, and
// the extension (if any).
//
// See also parser::expand_name_pattern() if changing anything here.
//
try
{
n.canonicalize ();
}
catch (const invalid_path& e)
{
fail (loc) << "invalid path '" << e.path << "'";
}
catch (const invalid_argument&)
{
// This is probably too general of a place to ignore multiple
// trailing slashes and treat it as a directory (e.g., we don't want
// to encourage this sloppiness in buildfiles). We could, however,
// do it for certain contexts, such as buildspec. Maybe a lax flag?
//
fail (loc) << "invalid name '" << v << "'";
}
// Extract the extension.
//
ext = target::split_name (v, loc);
}
// If the target type is still unknown, map it using the name/extension,
// falling back to file{}.
//
if (tt == nullptr)
{
// We only consider files without extension for file name mapping.
//
if (!ext)
tt = find_target_type_file (*this, v);
//@@ TODO: derive type from extension.
if (tt == nullptr)
tt = &file::static_type;
}
// If the target type does not use extensions but one was specified,
// factor it back into the name (this way we won't assert when printing
// diagnostics; see to_stream(target_key) for details).
//
if (ext &&
tt->fixed_extension == nullptr &&
tt->default_extension == nullptr)
{
v += '.';
v += *ext;
ext = nullopt;
}
return make_pair (tt, move (ext));
}
pair<const target_type&, optional<string>> scope::
find_target_type (name& n, name& o, const location& loc) const
{
auto r (find_target_type (n, loc));
if (r.first == nullptr)
fail (loc) << "unknown target type " << n.type << " in " << n;
bool src (n.pair); // If out-qualified, then it is from src.
if (src)
{
assert (n.pair == '@');
if (!o.directory ())
fail (loc) << "expected directory after '@'";
}
dir_path& d (n.dir);
const dir_path& sd (src_path ());
const dir_path& od (out_path ());
if (d.empty ())
d = src ? sd : od; // Already dormalized.
else
{
if (d.relative ())
d = (src ? sd : od) / d;
d.normalize ();
}
dir_path out;
if (src && sd != od) // If in source build, then out must be empty.
{
out = o.dir.relative () ? od / o.dir : move (o.dir);
out.normalize ();
}
o.dir = move (out); // Result.
return pair<const target_type&, optional<string>> (
*r.first, move (r.second));
}
target_key scope::
find_target_key (names& ns, const location& loc) const
{
if (size_t n = ns.size ())
{
if (n == (ns[0].pair ? 2 : 1))
{
name dummy;
return find_target_key (ns[0], n == 1 ? dummy : ns[1], loc);
}
}
fail (loc) << "invalid target name: " << ns << endf;
}
pair<const target_type&, optional<string>> scope::
find_prerequisite_type (name& n, name& o, const location& loc) const
{
auto r (find_target_type (n, loc));
if (r.first == nullptr)
fail (loc) << "unknown target type " << n.type << " in " << n;
if (n.pair) // If out-qualified, then it is from src.
{
assert (n.pair == '@');
if (!o.directory ())
fail (loc) << "expected directory after '@'";
}
if (!n.dir.empty ())
n.dir.normalize (false, true); // Current dir collapses to an empty one.
if (!o.dir.empty ())
o.dir.normalize (false, true); // Ditto.
return pair<const target_type&, optional<string>> (
*r.first, move (r.second));
}
prerequisite_key scope::
find_prerequisite_key (names& ns, const location& loc) const
{
if (size_t n = ns.size ())
{
if (n == (ns[0].pair ? 2 : 1))
{
name dummy;
return find_prerequisite_key (ns[0], n == 1 ? dummy : ns[1], loc);
}
}
fail (loc) << "invalid prerequisite name: " << ns << endf;
}
static target*
derived_tt_factory (context& c,
const target_type& t, dir_path d, dir_path o, string n)
{
// Pass our type to the base factory so that it can detect that it is
// being called to construct a derived target. This can be used, for
// example, to decide whether to "link up" to the group.
//
// One exception: if we are derived from a derived target type, then this
// logic would lead to infinite recursion. So in this case get the
// ultimate base.
//
const target_type* bt (t.base);
for (; bt->factory == &derived_tt_factory; bt = bt->base) ;
target* r (bt->factory (c, t, move (d), move (o), move (n)));
r->derived_type = &t;
return r;
}
pair<reference_wrapper<const target_type>, bool> scope::
derive_target_type (const string& name, const target_type& base)
{
assert (root_scope () == this);
// Base target type uses extensions.
//
bool ext (base.fixed_extension != nullptr ||
base.default_extension != nullptr);
// @@ Looks like we may need the ability to specify a fixed extension
// (which will be used to compare existing targets and not just
// search for existing files that is handled by the target_type::
// extension hook). See the file_factory() for details. We will
// probably need to specify it as part of the define directive (and
// have the ability to specify empty and NULL).
//
// Currently, if we define myfile{}: file{}, then myfile{foo} and
// myfile{foo.x} are the same target.
//
unique_ptr<target_type> dt (new target_type (base));
dt->base = &base;
dt->factory = &derived_tt_factory;
#if 0
// @@ We should probably inherit the fixed extension unless overriden with
// another fixed? But then any derivation from file{} will have to specify
// (or override) the fixed extension? But what is the use of deriving from
// a fixed extension target and not overriding its extension? Some kind of
// alias. Fuzzy.
//
dt->fixed_extension = nullptr /*&target_extension_fix<???>*/; // @@ TODO
// Override default extension/pattern derivation function: we most likely
// don't want to use the same default as our base (think cli: file). But,
// if our base doesn't use extensions, then most likely neither do we
// (think foo: alias).
//
dt->default_extension =
ext && dt->fixed_extension == nullptr
? &target_extension_var<nullptr>
: nullptr;
dt->pattern =
dt->fixed_extension != nullptr ? nullptr /*&target_pattern_fix<???>*/ :
dt->default_extension != nullptr ? &target_pattern_var<nullptr> :
nullptr;
// There is actually a difference between "fixed fixed" (like man1{}) and
// "fixed but overridable" (like file{}). Fuzzy: feels like there are
// different kinds of "fixed" (file{} vs man{} vs man1{}).
//
dt->print =
dt->fixed_extension != nullptr
? &target_print_0_ext_verb // Fixed extension, no use printing.
: nullptr; // Normal.
#endif
// An attempt to clarify the above mess:
//
// 1. If we have a "really fixed" extension (like man1{}) then we keep
// it (including pattern and print functions).
//
// 2. Otherwise, we make it target_extension_var.
//
// Note that this still mis-fires for the following scenarios:
//
// file{} -- What if the user does not set the default extension expecting
// similar semantics as file{} or man{} itself. Maybe explicit
// via attribute (i.e., inherit from base)?
//
// @@ Get the fallback extension from base target_extension_var
// somehow (we know the base target type so could just call it)?
//
if (ext)
{
if (dt->fixed_extension == nullptr ||
dt->fixed_extension == &target_extension_none ||
dt->fixed_extension == &target_extension_must)
{
dt->fixed_extension = nullptr;
dt->default_extension = &target_extension_var<nullptr>;
dt->pattern = &target_pattern_var<nullptr>;
dt->print = nullptr;
}
}
else
{
dt->fixed_extension = nullptr;
dt->default_extension = nullptr;
dt->pattern = nullptr;
dt->print = nullptr;
}
return root_extra->target_types.insert (name, move (dt));
}
const target_type& scope::
derive_target_type (const target_type& et)
{
assert (root_scope () == this);
unique_ptr<target_type> dt (new target_type (et));
dt->factory = &derived_tt_factory;
return root_extra->target_types.insert (et.name, move (dt)).first;
}
// scope_map
//
auto scope_map::
insert_out (const dir_path& k, bool root) -> iterator
{
auto er (map_.emplace (k, scopes ()));
if (er.second)
er.first->second.push_back (nullptr);
if (er.first->second.front () == nullptr)
{
er.first->second.front () = new scope (ctx, true /* shared */);
er.second = true;
}
scope& s (*er.first->second.front ());
// If this is a new scope, update the parent chain.
//
if (er.second)
{
scope* p (nullptr);
// Update scopes of which we are a new parent/root (unless this is the
// global scope). Also find our parent while at it.
//
if (map_.size () > 1)
{
// The first entry is ourselves.
//
auto r (map_.find_sub (k));
for (++r.first; r.first != r.second; ++r.first)
{
if (scope* c = r.first->second.front ())
{
// The first scope of which we are a parent is the least
// (shortest) one which means there is no other scope between it
// and our parent.
//
if (p == nullptr)
p = c->parent_;
if (root && c->root_ == p->root_) // No intermediate root.
c->root_ = &s;
if (p == c->parent_) // No intermediate parent.
c->parent_ = &s;
}
}
// We couldn't get the parent from one of its old children so we have
// to find it ourselves.
//
if (p == nullptr)
p = &find_out (k.directory ());
}
s.parent_ = p;
s.root_ = root ? &s : (p != nullptr ? p->root_ : nullptr);
}
else if (root && !s.root ())
{
// Upgrade to root scope.
//
auto r (map_.find_sub (k));
for (++r.first; r.first != r.second; ++r.first)
{
if (scope* c = r.first->second.front ())
{
if (c->root_ == s.root_) // No intermediate root.
c->root_ = &s;
}
}
s.root_ = &s;
}
return er.first;
}
auto scope_map::
insert_src (scope& s, const dir_path& k) -> iterator
{
auto er (map_.emplace (k, scopes ()));
if (er.second)
er.first->second.push_back (nullptr); // Owning out path entry.
// It doesn't feel like this function can possibly be called multiple
// times for the same scope and path so we skip the duplicate check.
//
er.first->second.push_back (&s);
return er.first;
}
scope& scope_map::
find_out (const dir_path& k)
{
assert (k.normalized (false)); // Allow non-canonical dir separators.
// This one is tricky: if we found an entry that doesn't contain the
// out path scope, then we need to consider outer scopes.
//
auto i (map_.find_sup_if (k,
[] (const pair<const dir_path, scopes>& v)
{
return v.second.front () != nullptr;
}));
assert (i != map_.end ()); // Should have at least global scope.
return *i->second.front ();
}
auto scope_map::
find (const dir_path& k) const -> pair<scopes::const_iterator,
scopes::const_iterator>
{
assert (k.normalized (false));
auto i (map_.find_sup (k));
assert (i != map_.end ());
auto b (i->second.begin ());
auto e (i->second.end ());
// Skip NULL first element.
//
if (*b == nullptr)
++b;
assert (b != e);
return make_pair (b, e);
}
}
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