8223657: Remove unused THREAD argument from SymbolTable functions
Summary: also made lookup and lookup_only functions private to SymbolTable. External callers use new_symbol or probe.
Reviewed-by: dholmes, gziemski
/*
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* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
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* under the terms of the GNU General Public License version 2 only, as
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*
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* 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
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*/
#include "precompiled.hpp"
#include "classfile/stackMapFrame.hpp"
#include "classfile/verifier.hpp"
#include "memory/resourceArea.hpp"
#include "oops/oop.inline.hpp"
#include "oops/symbol.hpp"
#include "runtime/handles.inline.hpp"
#include "utilities/globalDefinitions.hpp"
StackMapFrame::StackMapFrame(u2 max_locals, u2 max_stack, ClassVerifier* v) :
_offset(0), _locals_size(0), _stack_size(0),
_stack_mark(0), _max_locals(max_locals),
_max_stack(max_stack), _flags(0), _verifier(v) {
Thread* thr = v->thread();
_locals = NEW_RESOURCE_ARRAY_IN_THREAD(thr, VerificationType, max_locals);
_stack = NEW_RESOURCE_ARRAY_IN_THREAD(thr, VerificationType, max_stack);
int32_t i;
for(i = 0; i < max_locals; i++) {
_locals[i] = VerificationType::bogus_type();
}
for(i = 0; i < max_stack; i++) {
_stack[i] = VerificationType::bogus_type();
}
}
StackMapFrame* StackMapFrame::frame_in_exception_handler(u1 flags) {
Thread* thr = _verifier->thread();
VerificationType* stack = NEW_RESOURCE_ARRAY_IN_THREAD(thr, VerificationType, 1);
StackMapFrame* frame = new StackMapFrame(_offset, flags, _locals_size, 0, _max_locals, _max_stack, _locals, stack, _verifier);
return frame;
}
void StackMapFrame::initialize_object(
VerificationType old_object, VerificationType new_object) {
int32_t i;
for (i = 0; i < _max_locals; i++) {
if (_locals[i].equals(old_object)) {
_locals[i] = new_object;
}
}
for (i = 0; i < _stack_size; i++) {
if (_stack[i].equals(old_object)) {
_stack[i] = new_object;
}
}
if (old_object == VerificationType::uninitialized_this_type()) {
// "this" has been initialized - reset flags
_flags = 0;
}
}
VerificationType StackMapFrame::set_locals_from_arg(
const methodHandle& m, VerificationType thisKlass, TRAPS) {
SignatureStream ss(m->signature());
int init_local_num = 0;
if (!m->is_static()) {
init_local_num++;
// add one extra argument for instance method
if (m->name() == vmSymbols::object_initializer_name() &&
thisKlass.name() != vmSymbols::java_lang_Object()) {
_locals[0] = VerificationType::uninitialized_this_type();
_flags |= FLAG_THIS_UNINIT;
} else {
_locals[0] = thisKlass;
}
}
// local num may be greater than size of parameters because long/double occupies two slots
while(!ss.at_return_type()) {
init_local_num += _verifier->change_sig_to_verificationType(
&ss, &_locals[init_local_num]);
ss.next();
}
_locals_size = init_local_num;
switch (ss.type()) {
case T_OBJECT:
case T_ARRAY:
{
Symbol* sig = ss.as_symbol();
if (!sig->is_permanent()) {
// Create another symbol to save as signature stream unreferences
// this symbol.
Symbol *sig_copy =
verifier()->create_temporary_symbol(sig, 0, sig->utf8_length());
assert(sig_copy == sig, "symbols don't match");
sig = sig_copy;
}
return VerificationType::reference_type(sig);
}
case T_INT: return VerificationType::integer_type();
case T_BYTE: return VerificationType::byte_type();
case T_CHAR: return VerificationType::char_type();
case T_SHORT: return VerificationType::short_type();
case T_BOOLEAN: return VerificationType::boolean_type();
case T_FLOAT: return VerificationType::float_type();
case T_DOUBLE: return VerificationType::double_type();
case T_LONG: return VerificationType::long_type();
case T_VOID: return VerificationType::bogus_type();
default:
ShouldNotReachHere();
}
return VerificationType::bogus_type();
}
void StackMapFrame::copy_locals(const StackMapFrame* src) {
int32_t len = src->locals_size() < _locals_size ?
src->locals_size() : _locals_size;
for (int32_t i = 0; i < len; i++) {
_locals[i] = src->locals()[i];
}
}
void StackMapFrame::copy_stack(const StackMapFrame* src) {
int32_t len = src->stack_size() < _stack_size ?
src->stack_size() : _stack_size;
for (int32_t i = 0; i < len; i++) {
_stack[i] = src->stack()[i];
}
}
// Returns the location of the first mismatch, or 'len' if there are no
// mismatches
int StackMapFrame::is_assignable_to(
VerificationType* from, VerificationType* to, int32_t len, TRAPS) const {
int32_t i = 0;
for (i = 0; i < len; i++) {
if (!to[i].is_assignable_from(from[i], verifier(), false, THREAD)) {
break;
}
}
return i;
}
bool StackMapFrame::is_assignable_to(
const StackMapFrame* target, ErrorContext* ctx, TRAPS) const {
if (_max_locals != target->max_locals()) {
*ctx = ErrorContext::locals_size_mismatch(
_offset, (StackMapFrame*)this, (StackMapFrame*)target);
return false;
}
if (_stack_size != target->stack_size()) {
*ctx = ErrorContext::stack_size_mismatch(
_offset, (StackMapFrame*)this, (StackMapFrame*)target);
return false;
}
// Only need to compare type elements up to target->locals() or target->stack().
// The remaining type elements in this state can be ignored because they are
// assignable to bogus type.
int mismatch_loc;
mismatch_loc = is_assignable_to(
_locals, target->locals(), target->locals_size(), THREAD);
if (mismatch_loc != target->locals_size()) {
*ctx = ErrorContext::bad_type(target->offset(),
TypeOrigin::local(mismatch_loc, (StackMapFrame*)this),
TypeOrigin::sm_local(mismatch_loc, (StackMapFrame*)target));
return false;
}
mismatch_loc = is_assignable_to(_stack, target->stack(), _stack_size, THREAD);
if (mismatch_loc != _stack_size) {
*ctx = ErrorContext::bad_type(target->offset(),
TypeOrigin::stack(mismatch_loc, (StackMapFrame*)this),
TypeOrigin::sm_stack(mismatch_loc, (StackMapFrame*)target));
return false;
}
if ((_flags | target->flags()) == target->flags()) {
return true;
} else {
*ctx = ErrorContext::bad_flags(target->offset(),
(StackMapFrame*)this, (StackMapFrame*)target);
return false;
}
}
VerificationType StackMapFrame::pop_stack_ex(VerificationType type, TRAPS) {
if (_stack_size <= 0) {
verifier()->verify_error(
ErrorContext::stack_underflow(_offset, this),
"Operand stack underflow");
return VerificationType::bogus_type();
}
VerificationType top = _stack[--_stack_size];
bool subtype = type.is_assignable_from(
top, verifier(), false, CHECK_(VerificationType::bogus_type()));
if (!subtype) {
verifier()->verify_error(
ErrorContext::bad_type(_offset, stack_top_ctx(),
TypeOrigin::implicit(type)),
"Bad type on operand stack");
return VerificationType::bogus_type();
}
return top;
}
VerificationType StackMapFrame::get_local(
int32_t index, VerificationType type, TRAPS) {
if (index >= _max_locals) {
verifier()->verify_error(
ErrorContext::bad_local_index(_offset, index),
"Local variable table overflow");
return VerificationType::bogus_type();
}
bool subtype = type.is_assignable_from(_locals[index],
verifier(), false, CHECK_(VerificationType::bogus_type()));
if (!subtype) {
verifier()->verify_error(
ErrorContext::bad_type(_offset,
TypeOrigin::local(index, this),
TypeOrigin::implicit(type)),
"Bad local variable type");
return VerificationType::bogus_type();
}
if(index >= _locals_size) { _locals_size = index + 1; }
return _locals[index];
}
void StackMapFrame::get_local_2(
int32_t index, VerificationType type1, VerificationType type2, TRAPS) {
assert(type1.is_long() || type1.is_double(), "must be long/double");
assert(type2.is_long2() || type2.is_double2(), "must be long/double_2");
if (index >= _locals_size - 1) {
verifier()->verify_error(
ErrorContext::bad_local_index(_offset, index),
"get long/double overflows locals");
return;
}
bool subtype = type1.is_assignable_from(_locals[index], verifier(), false, CHECK);
if (!subtype) {
verifier()->verify_error(
ErrorContext::bad_type(_offset,
TypeOrigin::local(index, this), TypeOrigin::implicit(type1)),
"Bad local variable type");
} else {
subtype = type2.is_assignable_from(_locals[index + 1], verifier(), false, CHECK);
if (!subtype) {
/* Unreachable? All local store routines convert a split long or double
* into a TOP during the store. So we should never end up seeing an
* orphaned half. */
verifier()->verify_error(
ErrorContext::bad_type(_offset,
TypeOrigin::local(index + 1, this), TypeOrigin::implicit(type2)),
"Bad local variable type");
}
}
}
void StackMapFrame::set_local(int32_t index, VerificationType type, TRAPS) {
assert(!type.is_check(), "Must be a real type");
if (index >= _max_locals) {
verifier()->verify_error(
ErrorContext::bad_local_index(_offset, index),
"Local variable table overflow");
return;
}
// If type at index is double or long, set the next location to be unusable
if (_locals[index].is_double() || _locals[index].is_long()) {
assert((index + 1) < _locals_size, "Local variable table overflow");
_locals[index + 1] = VerificationType::bogus_type();
}
// If type at index is double_2 or long_2, set the previous location to be unusable
if (_locals[index].is_double2() || _locals[index].is_long2()) {
assert(index >= 1, "Local variable table underflow");
_locals[index - 1] = VerificationType::bogus_type();
}
_locals[index] = type;
if (index >= _locals_size) {
#ifdef ASSERT
for (int i=_locals_size; i<index; i++) {
assert(_locals[i] == VerificationType::bogus_type(),
"holes must be bogus type");
}
#endif
_locals_size = index + 1;
}
}
void StackMapFrame::set_local_2(
int32_t index, VerificationType type1, VerificationType type2, TRAPS) {
assert(type1.is_long() || type1.is_double(), "must be long/double");
assert(type2.is_long2() || type2.is_double2(), "must be long/double_2");
if (index >= _max_locals - 1) {
verifier()->verify_error(
ErrorContext::bad_local_index(_offset, index),
"Local variable table overflow");
return;
}
// If type at index+1 is double or long, set the next location to be unusable
if (_locals[index+1].is_double() || _locals[index+1].is_long()) {
assert((index + 2) < _locals_size, "Local variable table overflow");
_locals[index + 2] = VerificationType::bogus_type();
}
// If type at index is double_2 or long_2, set the previous location to be unusable
if (_locals[index].is_double2() || _locals[index].is_long2()) {
assert(index >= 1, "Local variable table underflow");
_locals[index - 1] = VerificationType::bogus_type();
}
_locals[index] = type1;
_locals[index+1] = type2;
if (index >= _locals_size - 1) {
#ifdef ASSERT
for (int i=_locals_size; i<index; i++) {
assert(_locals[i] == VerificationType::bogus_type(),
"holes must be bogus type");
}
#endif
_locals_size = index + 2;
}
}
TypeOrigin StackMapFrame::stack_top_ctx() {
return TypeOrigin::stack(_stack_size, this);
}
void StackMapFrame::print_on(outputStream* str) const {
str->indent().print_cr("bci: @%d", _offset);
str->indent().print_cr("flags: {%s }",
flag_this_uninit() ? " flagThisUninit" : "");
str->indent().print("locals: {");
for (int32_t i = 0; i < _locals_size; ++i) {
str->print(" ");
_locals[i].print_on(str);
if (i != _locals_size - 1) {
str->print(",");
}
}
str->print_cr(" }");
str->indent().print("stack: {");
for (int32_t j = 0; j < _stack_size; ++j) {
str->print(" ");
_stack[j].print_on(str);
if (j != _stack_size - 1) {
str->print(",");
}
}
str->print_cr(" }");
}