8234541: C1 emits an empty message when it inlines successfully
Summary: Use "inline" as the message when successfull
Reviewed-by: thartmann, mdoerr
Contributed-by: navy.xliu@gmail.com
/*
* Copyright (c) 2012, 2019, 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 "precompiled.hpp"
#include "memory/allocation.inline.hpp"
#include "memory/resourceArea.hpp"
#include "runtime/os.hpp"
#include "runtime/os_perf.hpp"
#include CPU_HEADER(vm_version_ext)
#ifdef __APPLE__
#import <libproc.h>
#include <sys/time.h>
#include <sys/sysctl.h>
#include <mach/mach.h>
#include <mach/task_info.h>
#include <sys/socket.h>
#include <net/if.h>
#include <net/if_dl.h>
#include <net/route.h>
#endif
static const double NANOS_PER_SEC = 1000000000.0;
class CPUPerformanceInterface::CPUPerformance : public CHeapObj<mtInternal> {
friend class CPUPerformanceInterface;
private:
long _total_cpu_nanos;
long _total_csr_nanos;
long _jvm_user_nanos;
long _jvm_system_nanos;
long _jvm_context_switches;
long _used_ticks;
long _total_ticks;
int _active_processor_count;
bool now_in_nanos(long* resultp) {
timeval current_time;
if (gettimeofday(¤t_time, NULL) != 0) {
// Error getting current time
return false;
}
*resultp = current_time.tv_sec * NANOS_PER_SEC + 1000L * current_time.tv_usec;
return true;
}
double normalize(double value) {
return MIN2<double>(MAX2<double>(value, 0.0), 1.0);
}
int cpu_load(int which_logical_cpu, double* cpu_load);
int context_switch_rate(double* rate);
int cpu_load_total_process(double* cpu_load);
int cpu_loads_process(double* pjvmUserLoad, double* pjvmKernelLoad, double* psystemTotalLoad);
CPUPerformance(const CPUPerformance& rhs); // no impl
CPUPerformance& operator=(const CPUPerformance& rhs); // no impl
public:
CPUPerformance();
bool initialize();
~CPUPerformance();
};
CPUPerformanceInterface::CPUPerformance::CPUPerformance() {
_total_cpu_nanos= 0;
_total_csr_nanos= 0;
_jvm_context_switches = 0;
_jvm_user_nanos = 0;
_jvm_system_nanos = 0;
_used_ticks = 0;
_total_ticks = 0;
_active_processor_count = 0;
}
bool CPUPerformanceInterface::CPUPerformance::initialize() {
return true;
}
CPUPerformanceInterface::CPUPerformance::~CPUPerformance() {
}
int CPUPerformanceInterface::CPUPerformance::cpu_load(int which_logical_cpu, double* cpu_load) {
return FUNCTIONALITY_NOT_IMPLEMENTED;
}
int CPUPerformanceInterface::CPUPerformance::cpu_load_total_process(double* cpu_load) {
#ifdef __APPLE__
host_name_port_t host = mach_host_self();
host_flavor_t flavor = HOST_CPU_LOAD_INFO;
mach_msg_type_number_t host_info_count = HOST_CPU_LOAD_INFO_COUNT;
host_cpu_load_info_data_t cpu_load_info;
kern_return_t kr = host_statistics(host, flavor, (host_info_t)&cpu_load_info, &host_info_count);
if (kr != KERN_SUCCESS) {
return OS_ERR;
}
long used_ticks = cpu_load_info.cpu_ticks[CPU_STATE_USER] + cpu_load_info.cpu_ticks[CPU_STATE_NICE] + cpu_load_info.cpu_ticks[CPU_STATE_SYSTEM];
long total_ticks = used_ticks + cpu_load_info.cpu_ticks[CPU_STATE_IDLE];
if (_used_ticks == 0 || _total_ticks == 0) {
// First call, just set the values
_used_ticks = used_ticks;
_total_ticks = total_ticks;
return OS_ERR;
}
long used_delta = used_ticks - _used_ticks;
long total_delta = total_ticks - _total_ticks;
_used_ticks = used_ticks;
_total_ticks = total_ticks;
if (total_delta == 0) {
// Avoid division by zero
return OS_ERR;
}
*cpu_load = (double)used_delta / total_delta;
return OS_OK;
#else
return FUNCTIONALITY_NOT_IMPLEMENTED;
#endif
}
int CPUPerformanceInterface::CPUPerformance::cpu_loads_process(double* pjvmUserLoad, double* pjvmKernelLoad, double* psystemTotalLoad) {
#ifdef __APPLE__
int result = cpu_load_total_process(psystemTotalLoad);
mach_port_t task = mach_task_self();
mach_msg_type_number_t task_info_count = TASK_INFO_MAX;
task_info_data_t task_info_data;
kern_return_t kr = task_info(task, TASK_ABSOLUTETIME_INFO, (task_info_t)task_info_data, &task_info_count);
if (kr != KERN_SUCCESS) {
return OS_ERR;
}
task_absolutetime_info_t absolutetime_info = (task_absolutetime_info_t)task_info_data;
int active_processor_count = os::active_processor_count();
long jvm_user_nanos = absolutetime_info->total_user;
long jvm_system_nanos = absolutetime_info->total_system;
long total_cpu_nanos;
if(!now_in_nanos(&total_cpu_nanos)) {
return OS_ERR;
}
if (_total_cpu_nanos == 0 || active_processor_count != _active_processor_count) {
// First call or change in active processor count
result = OS_ERR;
}
long delta_nanos = active_processor_count * (total_cpu_nanos - _total_cpu_nanos);
if (delta_nanos == 0) {
// Avoid division by zero
return OS_ERR;
}
*pjvmUserLoad = normalize((double)(jvm_user_nanos - _jvm_user_nanos)/delta_nanos);
*pjvmKernelLoad = normalize((double)(jvm_system_nanos - _jvm_system_nanos)/delta_nanos);
_active_processor_count = active_processor_count;
_total_cpu_nanos = total_cpu_nanos;
_jvm_user_nanos = jvm_user_nanos;
_jvm_system_nanos = jvm_system_nanos;
return result;
#else
return FUNCTIONALITY_NOT_IMPLEMENTED;
#endif
}
int CPUPerformanceInterface::CPUPerformance::context_switch_rate(double* rate) {
#ifdef __APPLE__
mach_port_t task = mach_task_self();
mach_msg_type_number_t task_info_count = TASK_INFO_MAX;
task_info_data_t task_info_data;
kern_return_t kr = task_info(task, TASK_EVENTS_INFO, (task_info_t)task_info_data, &task_info_count);
if (kr != KERN_SUCCESS) {
return OS_ERR;
}
int result = OS_OK;
if (_total_csr_nanos == 0 || _jvm_context_switches == 0) {
// First call just set initial values.
result = OS_ERR;
}
long jvm_context_switches = ((task_events_info_t)task_info_data)->csw;
long total_csr_nanos;
if(!now_in_nanos(&total_csr_nanos)) {
return OS_ERR;
}
double delta_in_sec = (double)(total_csr_nanos - _total_csr_nanos) / NANOS_PER_SEC;
if (delta_in_sec == 0.0) {
// Avoid division by zero
return OS_ERR;
}
*rate = (jvm_context_switches - _jvm_context_switches) / delta_in_sec;
_jvm_context_switches = jvm_context_switches;
_total_csr_nanos = total_csr_nanos;
return result;
#else
return FUNCTIONALITY_NOT_IMPLEMENTED;
#endif
}
CPUPerformanceInterface::CPUPerformanceInterface() {
_impl = NULL;
}
bool CPUPerformanceInterface::initialize() {
_impl = new CPUPerformanceInterface::CPUPerformance();
return _impl->initialize();
}
CPUPerformanceInterface::~CPUPerformanceInterface() {
if (_impl != NULL) {
delete _impl;
}
}
int CPUPerformanceInterface::cpu_load(int which_logical_cpu, double* cpu_load) const {
return _impl->cpu_load(which_logical_cpu, cpu_load);
}
int CPUPerformanceInterface::cpu_load_total_process(double* cpu_load) const {
return _impl->cpu_load_total_process(cpu_load);
}
int CPUPerformanceInterface::cpu_loads_process(double* pjvmUserLoad, double* pjvmKernelLoad, double* psystemTotalLoad) const {
return _impl->cpu_loads_process(pjvmUserLoad, pjvmKernelLoad, psystemTotalLoad);
}
int CPUPerformanceInterface::context_switch_rate(double* rate) const {
return _impl->context_switch_rate(rate);
}
class SystemProcessInterface::SystemProcesses : public CHeapObj<mtInternal> {
friend class SystemProcessInterface;
private:
SystemProcesses();
bool initialize();
SystemProcesses(const SystemProcesses& rhs); // no impl
SystemProcesses& operator=(const SystemProcesses& rhs); // no impl
~SystemProcesses();
//information about system processes
int system_processes(SystemProcess** system_processes, int* no_of_sys_processes) const;
};
SystemProcessInterface::SystemProcesses::SystemProcesses() {
}
bool SystemProcessInterface::SystemProcesses::initialize() {
return true;
}
SystemProcessInterface::SystemProcesses::~SystemProcesses() {
}
int SystemProcessInterface::SystemProcesses::system_processes(SystemProcess** system_processes, int* no_of_sys_processes) const {
assert(system_processes != NULL, "system_processes pointer is NULL!");
assert(no_of_sys_processes != NULL, "system_processes counter pointer is NULL!");
#ifdef __APPLE__
pid_t* pids = NULL;
int pid_count = 0;
ResourceMark rm;
int try_count = 0;
while (pids == NULL) {
// Find out buffer size
size_t pids_bytes = proc_listpids(PROC_ALL_PIDS, 0, NULL, 0);
if (pids_bytes <= 0) {
return OS_ERR;
}
pid_count = pids_bytes / sizeof(pid_t);
pids = NEW_RESOURCE_ARRAY(pid_t, pid_count);
memset(pids, 0, pids_bytes);
pids_bytes = proc_listpids(PROC_ALL_PIDS, 0, pids, pids_bytes);
if (pids_bytes <= 0) {
// couldn't fit buffer, retry.
FREE_RESOURCE_ARRAY(pid_t, pids, pid_count);
pids = NULL;
try_count++;
if (try_count > 3) {
return OS_ERR;
}
} else {
pid_count = pids_bytes / sizeof(pid_t);
}
}
int process_count = 0;
SystemProcess* next = NULL;
for (int i = 0; i < pid_count; i++) {
pid_t pid = pids[i];
if (pid != 0) {
char buffer[PROC_PIDPATHINFO_MAXSIZE];
memset(buffer, 0 , sizeof(buffer));
if (proc_pidpath(pid, buffer, sizeof(buffer)) != -1) {
int length = strlen(buffer);
if (length > 0) {
SystemProcess* current = new SystemProcess();
char * path = NEW_C_HEAP_ARRAY(char, length + 1, mtInternal);
strcpy(path, buffer);
current->set_path(path);
current->set_pid((int)pid);
current->set_next(next);
next = current;
process_count++;
}
}
}
}
*no_of_sys_processes = process_count;
*system_processes = next;
return OS_OK;
#endif
return FUNCTIONALITY_NOT_IMPLEMENTED;
}
int SystemProcessInterface::system_processes(SystemProcess** system_procs, int* no_of_sys_processes) const {
return _impl->system_processes(system_procs, no_of_sys_processes);
}
SystemProcessInterface::SystemProcessInterface() {
_impl = NULL;
}
bool SystemProcessInterface::initialize() {
_impl = new SystemProcessInterface::SystemProcesses();
return _impl->initialize();
}
SystemProcessInterface::~SystemProcessInterface() {
if (_impl != NULL) {
delete _impl;
}
}
CPUInformationInterface::CPUInformationInterface() {
_cpu_info = NULL;
}
bool CPUInformationInterface::initialize() {
_cpu_info = new CPUInformation();
_cpu_info->set_number_of_hardware_threads(VM_Version_Ext::number_of_threads());
_cpu_info->set_number_of_cores(VM_Version_Ext::number_of_cores());
_cpu_info->set_number_of_sockets(VM_Version_Ext::number_of_sockets());
_cpu_info->set_cpu_name(VM_Version_Ext::cpu_name());
_cpu_info->set_cpu_description(VM_Version_Ext::cpu_description());
return true;
}
CPUInformationInterface::~CPUInformationInterface() {
if (_cpu_info != NULL) {
if (_cpu_info->cpu_name() != NULL) {
const char* cpu_name = _cpu_info->cpu_name();
FREE_C_HEAP_ARRAY(char, cpu_name);
_cpu_info->set_cpu_name(NULL);
}
if (_cpu_info->cpu_description() != NULL) {
const char* cpu_desc = _cpu_info->cpu_description();
FREE_C_HEAP_ARRAY(char, cpu_desc);
_cpu_info->set_cpu_description(NULL);
}
delete _cpu_info;
}
}
int CPUInformationInterface::cpu_information(CPUInformation& cpu_info) {
if (NULL == _cpu_info) {
return OS_ERR;
}
cpu_info = *_cpu_info; // shallow copy assignment
return OS_OK;
}
class NetworkPerformanceInterface::NetworkPerformance : public CHeapObj<mtInternal> {
friend class NetworkPerformanceInterface;
private:
NetworkPerformance();
NetworkPerformance(const NetworkPerformance& rhs); // no impl
NetworkPerformance& operator=(const NetworkPerformance& rhs); // no impl
bool initialize();
~NetworkPerformance();
int network_utilization(NetworkInterface** network_interfaces) const;
};
NetworkPerformanceInterface::NetworkPerformance::NetworkPerformance() {
}
bool NetworkPerformanceInterface::NetworkPerformance::initialize() {
return true;
}
NetworkPerformanceInterface::NetworkPerformance::~NetworkPerformance() {
}
int NetworkPerformanceInterface::NetworkPerformance::network_utilization(NetworkInterface** network_interfaces) const {
size_t len;
int mib[] = {CTL_NET, PF_ROUTE, /* protocol number */ 0, /* address family */ 0, NET_RT_IFLIST2, /* NET_RT_FLAGS mask*/ 0};
if (sysctl(mib, sizeof(mib) / sizeof(mib[0]), NULL, &len, NULL, 0) != 0) {
return OS_ERR;
}
uint8_t* buf = NEW_RESOURCE_ARRAY(uint8_t, len);
if (sysctl(mib, sizeof(mib) / sizeof(mib[0]), buf, &len, NULL, 0) != 0) {
return OS_ERR;
}
size_t index = 0;
NetworkInterface* ret = NULL;
while (index < len) {
if_msghdr* msghdr = reinterpret_cast<if_msghdr*>(buf + index);
index += msghdr->ifm_msglen;
if (msghdr->ifm_type != RTM_IFINFO2) {
continue;
}
if_msghdr2* msghdr2 = reinterpret_cast<if_msghdr2*>(msghdr);
sockaddr_dl* sockaddr = reinterpret_cast<sockaddr_dl*>(msghdr2 + 1);
// The interface name is not necessarily NUL-terminated
char name_buf[128];
size_t name_len = MIN2(sizeof(name_buf) - 1, static_cast<size_t>(sockaddr->sdl_nlen));
strncpy(name_buf, sockaddr->sdl_data, name_len);
name_buf[name_len] = '\0';
uint64_t bytes_in = msghdr2->ifm_data.ifi_ibytes;
uint64_t bytes_out = msghdr2->ifm_data.ifi_obytes;
NetworkInterface* cur = new NetworkInterface(name_buf, bytes_in, bytes_out, ret);
ret = cur;
}
*network_interfaces = ret;
return OS_OK;
}
NetworkPerformanceInterface::NetworkPerformanceInterface() {
_impl = NULL;
}
NetworkPerformanceInterface::~NetworkPerformanceInterface() {
if (_impl != NULL) {
delete _impl;
}
}
bool NetworkPerformanceInterface::initialize() {
_impl = new NetworkPerformanceInterface::NetworkPerformance();
return _impl->initialize();
}
int NetworkPerformanceInterface::network_utilization(NetworkInterface** network_interfaces) const {
return _impl->network_utilization(network_interfaces);
}