6939203: JSR 292 needs method handle constants
Summary: Add new CP types CONSTANT_MethodHandle, CONSTANT_MethodType; extend 'ldc' bytecode.
Reviewed-by: twisti, never
/*
* Copyright (c) 1997, 2008, Oracle and/or its affiliates. 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 "incls/_precompiled.incl"
# include "incls/_globals.cpp.incl"
RUNTIME_FLAGS(MATERIALIZE_DEVELOPER_FLAG, MATERIALIZE_PD_DEVELOPER_FLAG, \
MATERIALIZE_PRODUCT_FLAG, MATERIALIZE_PD_PRODUCT_FLAG, \
MATERIALIZE_DIAGNOSTIC_FLAG, MATERIALIZE_EXPERIMENTAL_FLAG, \
MATERIALIZE_NOTPRODUCT_FLAG, \
MATERIALIZE_MANAGEABLE_FLAG, MATERIALIZE_PRODUCT_RW_FLAG, \
MATERIALIZE_LP64_PRODUCT_FLAG)
RUNTIME_OS_FLAGS(MATERIALIZE_DEVELOPER_FLAG, MATERIALIZE_PD_DEVELOPER_FLAG, \
MATERIALIZE_PRODUCT_FLAG, MATERIALIZE_PD_PRODUCT_FLAG, \
MATERIALIZE_DIAGNOSTIC_FLAG, MATERIALIZE_NOTPRODUCT_FLAG)
bool Flag::is_unlocker() const {
return strcmp(name, "UnlockDiagnosticVMOptions") == 0 ||
strcmp(name, "UnlockExperimentalVMOptions") == 0;
}
bool Flag::is_unlocked() const {
if (strcmp(kind, "{diagnostic}") == 0) {
return UnlockDiagnosticVMOptions;
} else if (strcmp(kind, "{experimental}") == 0 ||
strcmp(kind, "{C2 experimental}") == 0) {
return UnlockExperimentalVMOptions;
} else {
return true;
}
}
bool Flag::is_writeable() const {
return (strcmp(kind, "{manageable}") == 0 || strcmp(kind, "{product rw}") == 0);
}
// All flags except "manageable" are assumed internal flags.
// Long term, we need to define a mechanism to specify which flags
// are external/stable and change this function accordingly.
bool Flag::is_external() const {
return (strcmp(kind, "{manageable}") == 0);
}
// Length of format string (e.g. "%.1234s") for printing ccstr below
#define FORMAT_BUFFER_LEN 16
void Flag::print_on(outputStream* st) {
st->print("%5s %-35s %c= ", type, name, (origin != DEFAULT ? ':' : ' '));
if (is_bool()) st->print("%-16s", get_bool() ? "true" : "false");
if (is_intx()) st->print("%-16ld", get_intx());
if (is_uintx()) st->print("%-16lu", get_uintx());
if (is_uint64_t()) st->print("%-16lu", get_uint64_t());
if (is_ccstr()) {
const char* cp = get_ccstr();
if (cp != NULL) {
const char* eol;
while ((eol = strchr(cp, '\n')) != NULL) {
char format_buffer[FORMAT_BUFFER_LEN];
size_t llen = pointer_delta(eol, cp, sizeof(char));
jio_snprintf(format_buffer, FORMAT_BUFFER_LEN,
"%%." SIZE_FORMAT "s", llen);
st->print(format_buffer, cp);
st->cr();
cp = eol+1;
st->print("%5s %-35s += ", "", name);
}
st->print("%-16s", cp);
}
}
st->print(" %s", kind);
st->cr();
}
void Flag::print_as_flag(outputStream* st) {
if (is_bool()) {
st->print("-XX:%s%s", get_bool() ? "+" : "-", name);
} else if (is_intx()) {
st->print("-XX:%s=" INTX_FORMAT, name, get_intx());
} else if (is_uintx()) {
st->print("-XX:%s=" UINTX_FORMAT, name, get_uintx());
} else if (is_uint64_t()) {
st->print("-XX:%s=" UINT64_FORMAT, name, get_uint64_t());
} else if (is_ccstr()) {
st->print("-XX:%s=", name);
const char* cp = get_ccstr();
if (cp != NULL) {
// Need to turn embedded '\n's back into separate arguments
// Not so efficient to print one character at a time,
// but the choice is to do the transformation to a buffer
// and print that. And this need not be efficient.
for (; *cp != '\0'; cp += 1) {
switch (*cp) {
default:
st->print("%c", *cp);
break;
case '\n':
st->print(" -XX:%s=", name);
break;
}
}
}
} else {
ShouldNotReachHere();
}
}
// 4991491 do not "optimize out" the was_set false values: omitting them
// tickles a Microsoft compiler bug causing flagTable to be malformed
#define RUNTIME_PRODUCT_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{product}", DEFAULT },
#define RUNTIME_PD_PRODUCT_FLAG_STRUCT(type, name, doc) { #type, XSTR(name), &name, "{pd product}", DEFAULT },
#define RUNTIME_DIAGNOSTIC_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{diagnostic}", DEFAULT },
#define RUNTIME_EXPERIMENTAL_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{experimental}", DEFAULT },
#define RUNTIME_MANAGEABLE_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{manageable}", DEFAULT },
#define RUNTIME_PRODUCT_RW_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{product rw}", DEFAULT },
#ifdef PRODUCT
#define RUNTIME_DEVELOP_FLAG_STRUCT(type, name, value, doc) /* flag is constant */
#define RUNTIME_PD_DEVELOP_FLAG_STRUCT(type, name, doc) /* flag is constant */
#define RUNTIME_NOTPRODUCT_FLAG_STRUCT(type, name, value, doc)
#else
#define RUNTIME_DEVELOP_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "", DEFAULT },
#define RUNTIME_PD_DEVELOP_FLAG_STRUCT(type, name, doc) { #type, XSTR(name), &name, "{pd}", DEFAULT },
#define RUNTIME_NOTPRODUCT_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{notproduct}", DEFAULT },
#endif
#ifdef _LP64
#define RUNTIME_LP64_PRODUCT_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{lp64_product}", DEFAULT },
#else
#define RUNTIME_LP64_PRODUCT_FLAG_STRUCT(type, name, value, doc) /* flag is constant */
#endif // _LP64
#define C1_PRODUCT_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{C1 product}", DEFAULT },
#define C1_PD_PRODUCT_FLAG_STRUCT(type, name, doc) { #type, XSTR(name), &name, "{C1 pd product}", DEFAULT },
#ifdef PRODUCT
#define C1_DEVELOP_FLAG_STRUCT(type, name, value, doc) /* flag is constant */
#define C1_PD_DEVELOP_FLAG_STRUCT(type, name, doc) /* flag is constant */
#define C1_NOTPRODUCT_FLAG_STRUCT(type, name, value, doc)
#else
#define C1_DEVELOP_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{C1}", DEFAULT },
#define C1_PD_DEVELOP_FLAG_STRUCT(type, name, doc) { #type, XSTR(name), &name, "{C1 pd}", DEFAULT },
#define C1_NOTPRODUCT_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{C1 notproduct}", DEFAULT },
#endif
#define C2_PRODUCT_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{C2 product}", DEFAULT },
#define C2_PD_PRODUCT_FLAG_STRUCT(type, name, doc) { #type, XSTR(name), &name, "{C2 pd product}", DEFAULT },
#define C2_DIAGNOSTIC_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{C2 diagnostic}", DEFAULT },
#define C2_EXPERIMENTAL_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{C2 experimental}", DEFAULT },
#ifdef PRODUCT
#define C2_DEVELOP_FLAG_STRUCT(type, name, value, doc) /* flag is constant */
#define C2_PD_DEVELOP_FLAG_STRUCT(type, name, doc) /* flag is constant */
#define C2_NOTPRODUCT_FLAG_STRUCT(type, name, value, doc)
#else
#define C2_DEVELOP_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{C2}", DEFAULT },
#define C2_PD_DEVELOP_FLAG_STRUCT(type, name, doc) { #type, XSTR(name), &name, "{C2 pd}", DEFAULT },
#define C2_NOTPRODUCT_FLAG_STRUCT(type, name, value, doc) { #type, XSTR(name), &name, "{C2 notproduct}", DEFAULT },
#endif
static Flag flagTable[] = {
RUNTIME_FLAGS(RUNTIME_DEVELOP_FLAG_STRUCT, RUNTIME_PD_DEVELOP_FLAG_STRUCT, RUNTIME_PRODUCT_FLAG_STRUCT, RUNTIME_PD_PRODUCT_FLAG_STRUCT, RUNTIME_DIAGNOSTIC_FLAG_STRUCT, RUNTIME_EXPERIMENTAL_FLAG_STRUCT, RUNTIME_NOTPRODUCT_FLAG_STRUCT, RUNTIME_MANAGEABLE_FLAG_STRUCT, RUNTIME_PRODUCT_RW_FLAG_STRUCT, RUNTIME_LP64_PRODUCT_FLAG_STRUCT)
RUNTIME_OS_FLAGS(RUNTIME_DEVELOP_FLAG_STRUCT, RUNTIME_PD_DEVELOP_FLAG_STRUCT, RUNTIME_PRODUCT_FLAG_STRUCT, RUNTIME_PD_PRODUCT_FLAG_STRUCT, RUNTIME_DIAGNOSTIC_FLAG_STRUCT, RUNTIME_NOTPRODUCT_FLAG_STRUCT)
#ifndef SERIALGC
G1_FLAGS(RUNTIME_DEVELOP_FLAG_STRUCT, RUNTIME_PD_DEVELOP_FLAG_STRUCT, RUNTIME_PRODUCT_FLAG_STRUCT, RUNTIME_PD_PRODUCT_FLAG_STRUCT, RUNTIME_DIAGNOSTIC_FLAG_STRUCT, RUNTIME_EXPERIMENTAL_FLAG_STRUCT, RUNTIME_NOTPRODUCT_FLAG_STRUCT, RUNTIME_MANAGEABLE_FLAG_STRUCT, RUNTIME_PRODUCT_RW_FLAG_STRUCT)
#endif // SERIALGC
#ifdef COMPILER1
C1_FLAGS(C1_DEVELOP_FLAG_STRUCT, C1_PD_DEVELOP_FLAG_STRUCT, C1_PRODUCT_FLAG_STRUCT, C1_PD_PRODUCT_FLAG_STRUCT, C1_NOTPRODUCT_FLAG_STRUCT)
#endif
#ifdef COMPILER2
C2_FLAGS(C2_DEVELOP_FLAG_STRUCT, C2_PD_DEVELOP_FLAG_STRUCT, C2_PRODUCT_FLAG_STRUCT, C2_PD_PRODUCT_FLAG_STRUCT, C2_DIAGNOSTIC_FLAG_STRUCT, C2_EXPERIMENTAL_FLAG_STRUCT, C2_NOTPRODUCT_FLAG_STRUCT)
#endif
{0, NULL, NULL}
};
Flag* Flag::flags = flagTable;
size_t Flag::numFlags = (sizeof(flagTable) / sizeof(Flag));
inline bool str_equal(const char* s, char* q, size_t len) {
// s is null terminated, q is not!
if (strlen(s) != (unsigned int) len) return false;
return strncmp(s, q, len) == 0;
}
Flag* Flag::find_flag(char* name, size_t length) {
for (Flag* current = &flagTable[0]; current->name; current++) {
if (str_equal(current->name, name, length)) {
if (!(current->is_unlocked() || current->is_unlocker())) {
// disable use of diagnostic or experimental flags until they
// are explicitly unlocked
return NULL;
}
return current;
}
}
return NULL;
}
// Returns the address of the index'th element
static Flag* address_of_flag(CommandLineFlagWithType flag) {
assert((size_t)flag < Flag::numFlags, "bad command line flag index");
return &Flag::flags[flag];
}
bool CommandLineFlagsEx::is_default(CommandLineFlag flag) {
assert((size_t)flag < Flag::numFlags, "bad command line flag index");
Flag* f = &Flag::flags[flag];
return (f->origin == DEFAULT);
}
bool CommandLineFlagsEx::is_ergo(CommandLineFlag flag) {
assert((size_t)flag < Flag::numFlags, "bad command line flag index");
Flag* f = &Flag::flags[flag];
return (f->origin == ERGONOMIC);
}
bool CommandLineFlagsEx::is_cmdline(CommandLineFlag flag) {
assert((size_t)flag < Flag::numFlags, "bad command line flag index");
Flag* f = &Flag::flags[flag];
return (f->origin == COMMAND_LINE);
}
bool CommandLineFlags::wasSetOnCmdline(const char* name, bool* value) {
Flag* result = Flag::find_flag((char*)name, strlen(name));
if (result == NULL) return false;
*value = (result->origin == COMMAND_LINE);
return true;
}
bool CommandLineFlags::boolAt(char* name, size_t len, bool* value) {
Flag* result = Flag::find_flag(name, len);
if (result == NULL) return false;
if (!result->is_bool()) return false;
*value = result->get_bool();
return true;
}
bool CommandLineFlags::boolAtPut(char* name, size_t len, bool* value, FlagValueOrigin origin) {
Flag* result = Flag::find_flag(name, len);
if (result == NULL) return false;
if (!result->is_bool()) return false;
bool old_value = result->get_bool();
result->set_bool(*value);
*value = old_value;
result->origin = origin;
return true;
}
void CommandLineFlagsEx::boolAtPut(CommandLineFlagWithType flag, bool value, FlagValueOrigin origin) {
Flag* faddr = address_of_flag(flag);
guarantee(faddr != NULL && faddr->is_bool(), "wrong flag type");
faddr->set_bool(value);
faddr->origin = origin;
}
bool CommandLineFlags::intxAt(char* name, size_t len, intx* value) {
Flag* result = Flag::find_flag(name, len);
if (result == NULL) return false;
if (!result->is_intx()) return false;
*value = result->get_intx();
return true;
}
bool CommandLineFlags::intxAtPut(char* name, size_t len, intx* value, FlagValueOrigin origin) {
Flag* result = Flag::find_flag(name, len);
if (result == NULL) return false;
if (!result->is_intx()) return false;
intx old_value = result->get_intx();
result->set_intx(*value);
*value = old_value;
result->origin = origin;
return true;
}
void CommandLineFlagsEx::intxAtPut(CommandLineFlagWithType flag, intx value, FlagValueOrigin origin) {
Flag* faddr = address_of_flag(flag);
guarantee(faddr != NULL && faddr->is_intx(), "wrong flag type");
faddr->set_intx(value);
faddr->origin = origin;
}
bool CommandLineFlags::uintxAt(char* name, size_t len, uintx* value) {
Flag* result = Flag::find_flag(name, len);
if (result == NULL) return false;
if (!result->is_uintx()) return false;
*value = result->get_uintx();
return true;
}
bool CommandLineFlags::uintxAtPut(char* name, size_t len, uintx* value, FlagValueOrigin origin) {
Flag* result = Flag::find_flag(name, len);
if (result == NULL) return false;
if (!result->is_uintx()) return false;
uintx old_value = result->get_uintx();
result->set_uintx(*value);
*value = old_value;
result->origin = origin;
return true;
}
void CommandLineFlagsEx::uintxAtPut(CommandLineFlagWithType flag, uintx value, FlagValueOrigin origin) {
Flag* faddr = address_of_flag(flag);
guarantee(faddr != NULL && faddr->is_uintx(), "wrong flag type");
faddr->set_uintx(value);
faddr->origin = origin;
}
bool CommandLineFlags::uint64_tAt(char* name, size_t len, uint64_t* value) {
Flag* result = Flag::find_flag(name, len);
if (result == NULL) return false;
if (!result->is_uint64_t()) return false;
*value = result->get_uint64_t();
return true;
}
bool CommandLineFlags::uint64_tAtPut(char* name, size_t len, uint64_t* value, FlagValueOrigin origin) {
Flag* result = Flag::find_flag(name, len);
if (result == NULL) return false;
if (!result->is_uint64_t()) return false;
uint64_t old_value = result->get_uint64_t();
result->set_uint64_t(*value);
*value = old_value;
result->origin = origin;
return true;
}
void CommandLineFlagsEx::uint64_tAtPut(CommandLineFlagWithType flag, uint64_t value, FlagValueOrigin origin) {
Flag* faddr = address_of_flag(flag);
guarantee(faddr != NULL && faddr->is_uint64_t(), "wrong flag type");
faddr->set_uint64_t(value);
faddr->origin = origin;
}
bool CommandLineFlags::doubleAt(char* name, size_t len, double* value) {
Flag* result = Flag::find_flag(name, len);
if (result == NULL) return false;
if (!result->is_double()) return false;
*value = result->get_double();
return true;
}
bool CommandLineFlags::doubleAtPut(char* name, size_t len, double* value, FlagValueOrigin origin) {
Flag* result = Flag::find_flag(name, len);
if (result == NULL) return false;
if (!result->is_double()) return false;
double old_value = result->get_double();
result->set_double(*value);
*value = old_value;
result->origin = origin;
return true;
}
void CommandLineFlagsEx::doubleAtPut(CommandLineFlagWithType flag, double value, FlagValueOrigin origin) {
Flag* faddr = address_of_flag(flag);
guarantee(faddr != NULL && faddr->is_double(), "wrong flag type");
faddr->set_double(value);
faddr->origin = origin;
}
bool CommandLineFlags::ccstrAt(char* name, size_t len, ccstr* value) {
Flag* result = Flag::find_flag(name, len);
if (result == NULL) return false;
if (!result->is_ccstr()) return false;
*value = result->get_ccstr();
return true;
}
// Contract: Flag will make private copy of the incoming value.
// Outgoing value is always malloc-ed, and caller MUST call free.
bool CommandLineFlags::ccstrAtPut(char* name, size_t len, ccstr* value, FlagValueOrigin origin) {
Flag* result = Flag::find_flag(name, len);
if (result == NULL) return false;
if (!result->is_ccstr()) return false;
ccstr old_value = result->get_ccstr();
char* new_value = NULL;
if (*value != NULL) {
new_value = NEW_C_HEAP_ARRAY(char, strlen(*value)+1);
strcpy(new_value, *value);
}
result->set_ccstr(new_value);
if (result->origin == DEFAULT && old_value != NULL) {
// Prior value is NOT heap allocated, but was a literal constant.
char* old_value_to_free = NEW_C_HEAP_ARRAY(char, strlen(old_value)+1);
strcpy(old_value_to_free, old_value);
old_value = old_value_to_free;
}
*value = old_value;
result->origin = origin;
return true;
}
// Contract: Flag will make private copy of the incoming value.
void CommandLineFlagsEx::ccstrAtPut(CommandLineFlagWithType flag, ccstr value, FlagValueOrigin origin) {
Flag* faddr = address_of_flag(flag);
guarantee(faddr != NULL && faddr->is_ccstr(), "wrong flag type");
ccstr old_value = faddr->get_ccstr();
char* new_value = NEW_C_HEAP_ARRAY(char, strlen(value)+1);
strcpy(new_value, value);
faddr->set_ccstr(new_value);
if (faddr->origin != DEFAULT && old_value != NULL) {
// Prior value is heap allocated so free it.
FREE_C_HEAP_ARRAY(char, old_value);
}
faddr->origin = origin;
}
extern "C" {
static int compare_flags(const void* void_a, const void* void_b) {
return strcmp((*((Flag**) void_a))->name, (*((Flag**) void_b))->name);
}
}
void CommandLineFlags::printSetFlags() {
// Print which flags were set on the command line
// note: this method is called before the thread structure is in place
// which means resource allocation cannot be used.
// Compute size
int length= 0;
while (flagTable[length].name != NULL) length++;
// Sort
Flag** array = NEW_C_HEAP_ARRAY(Flag*, length);
for (int index = 0; index < length; index++) {
array[index] = &flagTable[index];
}
qsort(array, length, sizeof(Flag*), compare_flags);
// Print
for (int i = 0; i < length; i++) {
if (array[i]->origin /* naked field! */) {
array[i]->print_as_flag(tty);
tty->print(" ");
}
}
tty->cr();
FREE_C_HEAP_ARRAY(Flag*, array);
}
#ifndef PRODUCT
void CommandLineFlags::verify() {
assert(Arguments::check_vm_args_consistency(), "Some flag settings conflict");
}
#endif // PRODUCT
void CommandLineFlags::printFlags() {
// Print the flags sorted by name
// note: this method is called before the thread structure is in place
// which means resource allocation cannot be used.
// Compute size
int length= 0;
while (flagTable[length].name != NULL) length++;
// Sort
Flag** array = NEW_C_HEAP_ARRAY(Flag*, length);
for (int index = 0; index < length; index++) {
array[index] = &flagTable[index];
}
qsort(array, length, sizeof(Flag*), compare_flags);
// Print
tty->print_cr("[Global flags]");
for (int i = 0; i < length; i++) {
if (array[i]->is_unlocked()) {
array[i]->print_on(tty);
}
}
FREE_C_HEAP_ARRAY(Flag*, array);
}