8231844: Enhance type signature characters in classfile_constants.h and improve the JVM to use type signature characters more consistently
Summary: Increase the use of type signature constants instead of hard coded characters within the JVM.
Reviewed-by: coleenp, dholmes, fparain
Contributed-by: lois.foltan@oracle.com, john.r.rose@oracle.com
/*
* Copyright (c) 2018, Oracle and/or its affiliates. All rights reserved.
* Copyright (c) 2018 SAP SE. All rights reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
* or visit www.oracle.com if you need additional information or have any
* questions.
*
*/
#include "precompiled.hpp"
#include "classfile/classLoaderData.inline.hpp"
#include "classfile/classLoaderDataGraph.hpp"
#include "classfile/classLoaderHierarchyDCmd.hpp"
#include "memory/allocation.hpp"
#include "memory/resourceArea.hpp"
#include "runtime/safepoint.hpp"
#include "oops/reflectionAccessorImplKlassHelper.hpp"
#include "utilities/globalDefinitions.hpp"
#include "utilities/ostream.hpp"
ClassLoaderHierarchyDCmd::ClassLoaderHierarchyDCmd(outputStream* output, bool heap)
: DCmdWithParser(output, heap),
_show_classes("show-classes", "Print loaded classes.", "BOOLEAN", false, "false"),
_verbose("verbose", "Print detailed information.", "BOOLEAN", false, "false"),
_fold("fold", "Show loaders of the same name and class as one.", "BOOLEAN", true, "true") {
_dcmdparser.add_dcmd_option(&_show_classes);
_dcmdparser.add_dcmd_option(&_verbose);
_dcmdparser.add_dcmd_option(&_fold);
}
int ClassLoaderHierarchyDCmd::num_arguments() {
ResourceMark rm;
ClassLoaderHierarchyDCmd* dcmd = new ClassLoaderHierarchyDCmd(NULL, false);
if (dcmd != NULL) {
DCmdMark mark(dcmd);
return dcmd->_dcmdparser.num_arguments();
} else {
return 0;
}
}
// Helper class for drawing the branches to the left of a node.
class BranchTracker : public StackObj {
// "<x>"
// " |---<y>"
// " | |
// " | <z>"
// " | |---<z1>
// " | |---<z2>
// ^^^^^^^ ^^^
// A B
// Some terms for the graphics:
// - branch: vertical connection between a node's ancestor to a later sibling.
// - branchwork: (A) the string to print as a prefix at the start of each line, contains all branches.
// - twig (B): Length of the dashed line connecting a node to its branch.
// - branch spacing: how many spaces between branches are printed.
public:
enum { max_depth = 64, twig_len = 2, branch_spacing = 5 };
private:
char _branches[max_depth];
int _pos;
public:
BranchTracker()
: _pos(0) {}
void push(bool has_branch) {
if (_pos < max_depth) {
_branches[_pos] = has_branch ? '|' : ' ';
}
_pos ++; // beyond max depth, omit branch drawing but do count on.
}
void pop() {
assert(_pos > 0, "must be");
_pos --;
}
void print(outputStream* st) {
for (int i = 0; i < _pos; i ++) {
st->print("%c%.*s", _branches[i], branch_spacing, " ");
}
}
class Mark {
BranchTracker& _tr;
public:
Mark(BranchTracker& tr, bool has_branch_here)
: _tr(tr) { _tr.push(has_branch_here); }
~Mark() { _tr.pop(); }
};
}; // end: BranchTracker
struct LoadedClassInfo : public ResourceObj {
public:
LoadedClassInfo* _next;
Klass* const _klass;
const ClassLoaderData* const _cld;
LoadedClassInfo(Klass* klass, const ClassLoaderData* cld)
: _klass(klass), _cld(cld) {}
};
class LoaderTreeNode : public ResourceObj {
// We walk the CLDG and, for each CLD which is non-unsafe_anonymous, add
// a tree node.
// To add a node we need its parent node; if the parent node does not yet
// exist - because we have not yet encountered the CLD for the parent loader -
// we add a preliminary empty LoaderTreeNode for it. This preliminary node
// just contains the loader oop and nothing else. Once we encounter the CLD of
// this parent loader, we fill in all the other details.
const oop _loader_oop;
const ClassLoaderData* _cld;
LoaderTreeNode* _child;
LoaderTreeNode* _next;
LoadedClassInfo* _classes;
int _num_classes;
LoadedClassInfo* _anon_classes;
int _num_anon_classes;
// In default view, similar tree nodes (same loader class, same name or no name)
// are folded into each other to make the output more readable.
// _num_folded contains the number of nodes which have been folded into this
// one.
int _num_folded;
void print_with_childs(outputStream* st, BranchTracker& branchtracker,
bool print_classes, bool verbose) const {
ResourceMark rm;
if (_cld == NULL) {
// Not sure how this could happen: we added a preliminary node for a parent but then never encountered
// its CLD?
return;
}
// Retrieve information.
const Klass* const loader_klass = _cld->class_loader_klass();
const Symbol* const loader_name = _cld->name();
branchtracker.print(st);
// e.g. "+--- jdk.internal.reflect.DelegatingClassLoader"
st->print("+%.*s", BranchTracker::twig_len, "----------");
if (_cld->is_the_null_class_loader_data()) {
st->print(" <bootstrap>");
} else {
if (loader_name != NULL) {
st->print(" \"%s\",", loader_name->as_C_string());
}
st->print(" %s", loader_klass != NULL ? loader_klass->external_name() : "??");
if (_num_folded > 0) {
st->print(" (+ %d more)", _num_folded);
}
}
st->cr();
// Output following this node (node details and child nodes) - up to the next sibling node
// needs to be prefixed with "|" if there is a follow up sibling.
const bool have_sibling = _next != NULL;
BranchTracker::Mark trm(branchtracker, have_sibling);
{
// optional node details following this node needs to be prefixed with "|"
// if there are follow up child nodes.
const bool have_child = _child != NULL;
BranchTracker::Mark trm(branchtracker, have_child);
// Empty line
branchtracker.print(st);
st->cr();
const int indentation = 18;
if (verbose) {
branchtracker.print(st);
st->print_cr("%*s " PTR_FORMAT, indentation, "Loader Oop:", p2i(_loader_oop));
branchtracker.print(st);
st->print_cr("%*s " PTR_FORMAT, indentation, "Loader Data:", p2i(_cld));
branchtracker.print(st);
st->print_cr("%*s " PTR_FORMAT, indentation, "Loader Klass:", p2i(loader_klass));
// Empty line
branchtracker.print(st);
st->cr();
}
if (print_classes) {
if (_classes != NULL) {
for (LoadedClassInfo* lci = _classes; lci; lci = lci->_next) {
// Non-unsafe anonymous classes should live in the primary CLD of its loader
assert(lci->_cld == _cld, "must be");
branchtracker.print(st);
if (lci == _classes) { // first iteration
st->print("%*s ", indentation, "Classes:");
} else {
st->print("%*s ", indentation, "");
}
st->print("%s", lci->_klass->external_name());
// Special treatment for generated core reflection accessor classes: print invocation target.
if (ReflectionAccessorImplKlassHelper::is_generated_accessor(lci->_klass)) {
st->print(" (invokes: ");
ReflectionAccessorImplKlassHelper::print_invocation_target(st, lci->_klass);
st->print(")");
}
st->cr();
}
branchtracker.print(st);
st->print("%*s ", indentation, "");
st->print_cr("(%u class%s)", _num_classes, (_num_classes == 1) ? "" : "es");
// Empty line
branchtracker.print(st);
st->cr();
}
if (_anon_classes != NULL) {
for (LoadedClassInfo* lci = _anon_classes; lci; lci = lci->_next) {
branchtracker.print(st);
if (lci == _anon_classes) { // first iteration
st->print("%*s ", indentation, "Unsafe Anonymous Classes:");
} else {
st->print("%*s ", indentation, "");
}
st->print("%s", lci->_klass->external_name());
// For unsafe anonymous classes, also print CLD if verbose. Should be a different one than the primary CLD.
assert(lci->_cld != _cld, "must be");
if (verbose) {
st->print(" (Loader Data: " PTR_FORMAT ")", p2i(lci->_cld));
}
st->cr();
}
branchtracker.print(st);
st->print("%*s ", indentation, "");
st->print_cr("(%u unsafe anonymous class%s)", _num_anon_classes, (_num_anon_classes == 1) ? "" : "es");
// Empty line
branchtracker.print(st);
st->cr();
}
} // end: print_classes
} // Pop branchtracker mark
// Print children, recursively
LoaderTreeNode* c = _child;
while (c != NULL) {
c->print_with_childs(st, branchtracker, print_classes, verbose);
c = c->_next;
}
}
// Helper: Attempt to fold this node into the target node. If success, returns true.
// Folding can be done if both nodes are leaf nodes and they refer to the same loader class
// and they have the same name or no name (note: leaf check is done by caller).
bool can_fold_into(LoaderTreeNode* target_node) const {
assert(is_leaf() && target_node->is_leaf(), "must be leaf");
return _cld->class_loader_klass() == target_node->_cld->class_loader_klass() &&
_cld->name() == target_node->_cld->name();
}
public:
LoaderTreeNode(const oop loader_oop)
: _loader_oop(loader_oop), _cld(NULL), _child(NULL), _next(NULL),
_classes(NULL), _num_classes(0), _anon_classes(NULL), _num_anon_classes(0),
_num_folded(0)
{}
void set_cld(const ClassLoaderData* cld) {
_cld = cld;
}
void add_child(LoaderTreeNode* info) {
info->_next = _child;
_child = info;
}
void add_sibling(LoaderTreeNode* info) {
assert(info->_next == NULL, "must be");
info->_next = _next;
_next = info;
}
void add_classes(LoadedClassInfo* first_class, int num_classes, bool is_unsafe_anonymous) {
LoadedClassInfo** p_list_to_add_to = is_unsafe_anonymous ? &_anon_classes : &_classes;
// Search tail.
while ((*p_list_to_add_to) != NULL) {
p_list_to_add_to = &(*p_list_to_add_to)->_next;
}
*p_list_to_add_to = first_class;
if (is_unsafe_anonymous) {
_num_anon_classes += num_classes;
} else {
_num_classes += num_classes;
}
}
const ClassLoaderData* cld() const {
return _cld;
}
const oop loader_oop() const {
return _loader_oop;
}
LoaderTreeNode* find(const oop loader_oop) {
LoaderTreeNode* result = NULL;
if (_loader_oop == loader_oop) {
result = this;
} else {
LoaderTreeNode* c = _child;
while (c != NULL && result == NULL) {
result = c->find(loader_oop);
c = c->_next;
}
}
return result;
}
bool is_leaf() const { return _child == NULL; }
// Attempt to fold similar nodes among this node's children. We only fold leaf nodes
// (no child class loaders).
// For non-leaf nodes (class loaders with child class loaders), do this recursivly.
void fold_children() {
LoaderTreeNode* node = _child;
LoaderTreeNode* prev = NULL;
while (node != NULL) {
LoaderTreeNode* matching_node = NULL;
if (node->is_leaf()) {
// Look among the preceeding node siblings for a match.
for (LoaderTreeNode* node2 = _child; node2 != node && matching_node == NULL;
node2 = node2->_next) {
if (node2->is_leaf() && node->can_fold_into(node2)) {
matching_node = node2;
}
}
} else {
node->fold_children();
}
if (matching_node != NULL) {
// Increase fold count for the matching node and remove folded node from the child list.
matching_node->_num_folded ++;
assert(prev != NULL, "Sanity"); // can never happen since we do not fold the first node.
prev->_next = node->_next;
} else {
prev = node;
}
node = node->_next;
}
}
void print_with_childs(outputStream* st, bool print_classes, bool print_add_info) const {
BranchTracker bwt;
print_with_childs(st, bwt, print_classes, print_add_info);
}
};
class LoadedClassCollectClosure : public KlassClosure {
public:
LoadedClassInfo* _list;
const ClassLoaderData* _cld;
int _num_classes;
LoadedClassCollectClosure(const ClassLoaderData* cld)
: _list(NULL), _cld(cld), _num_classes(0) {}
void do_klass(Klass* k) {
LoadedClassInfo* lki = new LoadedClassInfo(k, _cld);
lki->_next = _list;
_list = lki;
_num_classes ++;
}
};
class LoaderInfoScanClosure : public CLDClosure {
const bool _print_classes;
const bool _verbose;
LoaderTreeNode* _root;
static void fill_in_classes(LoaderTreeNode* info, const ClassLoaderData* cld) {
assert(info != NULL && cld != NULL, "must be");
LoadedClassCollectClosure lccc(cld);
const_cast<ClassLoaderData*>(cld)->classes_do(&lccc);
if (lccc._num_classes > 0) {
info->add_classes(lccc._list, lccc._num_classes, cld->is_unsafe_anonymous());
}
}
LoaderTreeNode* find_node_or_add_empty_node(oop loader_oop) {
assert(_root != NULL, "root node must exist");
if (loader_oop == NULL) {
return _root;
}
// Check if a node for this oop already exists.
LoaderTreeNode* info = _root->find(loader_oop);
if (info == NULL) {
// It does not. Create a node.
info = new LoaderTreeNode(loader_oop);
// Add it to tree.
LoaderTreeNode* parent_info = NULL;
// Recursively add parent nodes if needed.
const oop parent_oop = java_lang_ClassLoader::parent(loader_oop);
if (parent_oop == NULL) {
parent_info = _root;
} else {
parent_info = find_node_or_add_empty_node(parent_oop);
}
assert(parent_info != NULL, "must be");
parent_info->add_child(info);
}
return info;
}
public:
LoaderInfoScanClosure(bool print_classes, bool verbose)
: _print_classes(print_classes), _verbose(verbose), _root(NULL) {
_root = new LoaderTreeNode(NULL);
}
void print_results(outputStream* st) const {
_root->print_with_childs(st, _print_classes, _verbose);
}
void do_cld (ClassLoaderData* cld) {
// We do not display unloading loaders, for now.
if (!cld->is_alive()) {
return;
}
const oop loader_oop = cld->class_loader();
LoaderTreeNode* info = find_node_or_add_empty_node(loader_oop);
assert(info != NULL, "must be");
// Update CLD in node, but only if this is the primary CLD for this loader.
if (cld->is_unsafe_anonymous() == false) {
assert(info->cld() == NULL, "there should be only one primary CLD per loader");
info->set_cld(cld);
}
// Add classes.
fill_in_classes(info, cld);
}
void fold() {
_root->fold_children();
}
};
class ClassLoaderHierarchyVMOperation : public VM_Operation {
outputStream* const _out;
const bool _show_classes;
const bool _verbose;
const bool _fold;
public:
ClassLoaderHierarchyVMOperation(outputStream* out, bool show_classes, bool verbose, bool fold) :
_out(out), _show_classes(show_classes), _verbose(verbose), _fold(fold)
{}
VMOp_Type type() const {
return VMOp_ClassLoaderHierarchyOperation;
}
void doit() {
assert(SafepointSynchronize::is_at_safepoint(), "must be a safepoint");
ResourceMark rm;
LoaderInfoScanClosure cl (_show_classes, _verbose);
ClassLoaderDataGraph::loaded_cld_do(&cl);
// In non-verbose and non-show-classes mode, attempt to fold the tree.
if (_fold) {
if (!_verbose && !_show_classes) {
cl.fold();
}
}
cl.print_results(_out);
}
};
// This command needs to be executed at a safepoint.
void ClassLoaderHierarchyDCmd::execute(DCmdSource source, TRAPS) {
ClassLoaderHierarchyVMOperation op(output(), _show_classes.value(), _verbose.value(), _fold.value());
VMThread::execute(&op);
}