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Quellcode-Bibliothek© Kompilation durch diese Firma[Weder Korrektheit noch Funktionsfähigkeit der Software werden zugesichert.]Datei: os_perf_windows.cpp Sprache: C |
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/*
* Copyright (c) 2012, 2021, 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 "iphlp_interface.hpp" #include "jvm_io.h" #include "logging/log.hpp" #include "memory/allocation.inline.hpp" #include "memory/resourceArea.hpp" #include "pdh_interface.hpp" #include "runtime/os_perf.hpp" #include "runtime/os.hpp" #include "runtime/semaphore.inline.hpp" #include "runtime/vm_version.hpp" #include "utilities/globalDefinitions.hpp" #include "utilities/macros.hpp" #include <math.h> #include <psapi.h> #include <TlHelp32.h> /* * Windows provides a vast plethora of performance objects and counters, * consumption of which is assisted using the Performance Data Helper (PDH) interface. * We import a selected few api entry points from PDH, see pdh_interface.hpp. * * The code located in this file is to a large extent an abstraction over much of the * plumbing needed to start consuming an object and/or counter of choice. * * * How to use: * 1. Create a query * 2. Add counters to the query * 3. Collect the performance data using the query * 4. Read the performance data from counters associated with the query * 5. Destroy query (counter destruction implied) * * * Every PDH artifact, like processor, process, thread, memory, and so forth are * identified with an index that is always the same irrespective * of the localized version of the operating system or service pack installed. * INFO: Using PDH APIs Correctly in a Localized Language (Q287159) * http://support.microsoft.com/default.aspx?scid=kb;EN-US;q287159 * * To find the correct index for an object or counter, inspect the registry key / value: * [HKEY_LOCAL_MACHINE\SOFTWARE\Microsoft\Windows NT\CurrentVersion\Perflib\009\Cou * * some common PDH indexes */ static const DWORD PDH_PROCESSOR_IDX = 238; static const DWORD PDH_PROCESSOR_TIME_IDX = 6; static const DWORD PDH_PRIV_PROCESSOR_TIME_IDX = 144; static const DWORD PDH_PROCESS_IDX = 230; static const DWORD PDH_ID_PROCESS_IDX = 784; static const DWORD PDH_CONTEXT_SWITCH_RATE_IDX = 146; static const DWORD PDH_SYSTEM_IDX = 2; /* useful pdh fmt's for the general form: \object(instance#index)\counter */ static const char* const OBJECT_COUNTER_FMT = "\\%s\\%s"; static const size_t OBJECT_COUNTER_FMT_LEN = 2; static const char* const OBJECT_WITH_INSTANCES_COUNTER_FMT = "\\%s(%s)\\%s"; static const size_t OBJECT_WITH_INSTANCES_COUNTER_FMT_LEN = 4; static const char* const PROCESS_OBJECT_WITH_INSTANCES_COUNTER_FMT = "\\%s(%s#%s)\\%s" static const size_t PROCESS_OBJECT_WITH_INSTANCES_COUNTER_FMT_LEN = 5; static const char* const PROCESS_OBJECT_WITH_INSTANCES_WILDCARD_FMT = "\\%s(%s*)\\%s"; static const size_t PROCESS_OBJECT_WITH_INSTANCES_WILDCARD_FMT_LEN = 5; /* pdh string constants built up from fmts on initialization */ static const char* process_image_name = NULL; // e.g. "java" but could have another image name static char* pdh_process_instance_IDProcess_counter_fmt = NULL; // "\Process(java#%d)\ static char* pdh_process_instance_wildcard_IDProcess_counter = NULL; // "\Process(java /* * Structs for PDH queries. */ typedef struct { HQUERY pdh_query_handle; s8 lastUpdate; // Last time query was updated. } UpdateQueryS, *UpdateQueryP; typedef struct { UpdateQueryS query; HCOUNTER counter; bool initialized; } CounterQueryS, *CounterQueryP; typedef struct { UpdateQueryS query; HCOUNTER* counters; int noOfCounters; bool initialized; } MultiCounterQueryS, *MultiCounterQueryP; typedef struct { MultiCounterQueryP queries; int size; bool initialized; } MultiCounterQuerySetS, *MultiCounterQuerySetP; typedef struct { MultiCounterQuerySetS set; int process_idx; } ProcessQueryS, *ProcessQueryP; static int open_query(HQUERY* pdh_query_handle) { return PdhDll::PdhOpenQuery(NULL, 0, pdh_query_handle) != ERROR_SUCCESS ? OS_ERR : OS_OK; } static int open_query(UpdateQueryP query) { return open_query(&query->pdh_query_handle); } template <typename QueryP> static int open_query(QueryP query) { return open_query(&query->query); } static void close_query(HQUERY* const pdh_query_handle, HCOUNTER* const counter) { if (counter != NULL && *counter != NULL) { PdhDll::PdhRemoveCounter(*counter); *counter = NULL; } if (pdh_query_handle != NULL && *pdh_query_handle != NULL) { PdhDll::PdhCloseQuery(*pdh_query_handle); *pdh_query_handle = NULL; } } static void close_query(MultiCounterQueryP query) { for (int i = 0; i < query->noOfCounters; ++i) { close_query(NULL, &query->counters[i]); } close_query(&query->query.pdh_query_handle, NULL); query->initialized = false; } static CounterQueryP create_counter_query() { CounterQueryP const query = NEW_C_HEAP_OBJ(CounterQueryS, mtInternal); memset(query, 0, sizeof(CounterQueryS)); return query; } static MultiCounterQueryP create_multi_counter_query() { MultiCounterQueryP const query = NEW_C_HEAP_ARRAY(MultiCounterQueryS, 1, mtInternal); memset(query, 0, sizeof(MultiCounterQueryS)); return query; } static void destroy(CounterQueryP query) { assert(query != NULL, "invariant"); close_query(&query->query.pdh_query_handle, &query->counter); FREE_C_HEAP_OBJ(query); } static void destroy(MultiCounterQueryP query) { if (query != NULL) { for (int i = 0; i < query->noOfCounters; ++i) { close_query(NULL, &query->counters[i]); } FREE_C_HEAP_ARRAY(char, query->counters); close_query(&query->query.pdh_query_handle, NULL); FREE_C_HEAP_ARRAY(MultiCounterQueryS, query); } } static void destroy_query_set(MultiCounterQuerySetP query_set) { for (int i = 0; i < query_set->size; i++) { for (int j = 0; j < query_set->queries[i].noOfCounters; ++j) { close_query(NULL, &query_set->queries[i].counters[j]); } FREE_C_HEAP_ARRAY(char, query_set->queries[i].counters); close_query(&query_set->queries[i].query.pdh_query_handle, NULL); } FREE_C_HEAP_ARRAY(MultiCounterQueryS, query_set->queries); } static void destroy(MultiCounterQuerySetP query) { destroy_query_set(query); FREE_C_HEAP_ARRAY(MultiCounterQuerySetS, query); } static void destroy(ProcessQueryP query) { destroy_query_set(&query->set); FREE_C_HEAP_OBJ(query); } static void allocate_counters(MultiCounterQueryP query, size_t nofCounters) { assert(query != NULL, "invariant"); assert(!query->initialized, "invariant"); assert(0 == query->noOfCounters, "invariant"); assert(query->counters == NULL, "invariant"); query->counters = NEW_C_HEAP_ARRAY(HCOUNTER, nofCounters, mtInternal); memset(query->counters, 0, nofCounters * sizeof(HCOUNTER)); query->noOfCounters = (int)nofCounters; } static void allocate_counters(MultiCounterQuerySetP query, size_t nofCounters) { assert(query != NULL, "invariant"); assert(!query->initialized, "invariant"); for (int i = 0; i < query->size; ++i) { allocate_counters(&query->queries[i], nofCounters); } } static void allocate_counters(ProcessQueryP query, size_t nofCounters) { assert(query != NULL, "invariant"); allocate_counters(&query->set, nofCounters); } static void deallocate_counters(MultiCounterQueryP query) { FREE_C_HEAP_ARRAY(char, query->counters); query->counters = NULL; query->noOfCounters = 0; } static OSReturn add_counter(UpdateQueryP query, HCOUNTER* counter, const char* counter_p assert(query != NULL, "invariant"); assert(counter != NULL, "invariant"); assert(counter_path != NULL, "invariant"); if (query->pdh_query_handle == NULL) { if (open_query(query) != OS_OK) { return OS_ERR; } } assert(query->pdh_query_handle != NULL, "invariant"); PDH_STATUS status = PdhDll::PdhAddCounter(query->pdh_query_handle, counter_path, 0, cou if (PDH_CSTATUS_NO_OBJECT == status || PDH_CSTATUS_NO_COUNTER == status) { return OS_ERR; } /* * According to the MSDN documentation, rate counters must be read twice: * * "Obtaining the value of rate counters such as Page faults/sec requires that * PdhCollectQueryData be called twice, with a specific time interval between * the two calls, before calling PdhGetFormattedCounterValue. Call Sleep to * implement the waiting period between the two calls to PdhCollectQueryData." * * Take the first sample here already to allow for the next "real" sample * to succeed. */ if (first_sample_on_init && PdhDll::PdhCollectQueryData(query->pdh_query_handle) != ERRO return OS_ERR; } return OS_OK; } template <typename QueryP> static OSReturn add_counter(QueryP query, HCOUNTER* counter, const char* counter_path, bo assert(query != NULL, "invariant"); assert(counter != NULL, "invariant"); assert(counter_path != NULL, "invariant"); return add_counter(&query->query, counter, counter_path, first_sample_on_init); } // if add_counter fails with OS_ERR, the performance counter might be disabled in the registry static OSReturn add_counter(CounterQueryP query, const char* counter_path, bool first_sa return add_counter(query, &query->counter, counter_path, first_sample_on_init); } static OSReturn add_counter(MultiCounterQueryP query, int counter_idx, const char* count assert(query != NULL, "invariant"); assert(counter_idx < query->noOfCounters, "invariant"); assert(query->counters[counter_idx] == NULL, "invariant"); return add_counter(query, &query->counters[counter_idx], counter_path, first_sample_on_in } // Need to limit how often we update a query to minimize the heisenberg effect. // (PDH behaves erratically if the counters are queried too often, especially counters that // store and use values from two consecutive updates, like cpu load.) static const int min_update_interval_millis = 500; static int collect(UpdateQueryP query) { assert(query != NULL, "invariant"); const s8 now = os::javaTimeNanos(); if (nanos_to_millis(now - query->lastUpdate) > min_update_interval_millis) { if (PdhDll::PdhCollectQueryData(query->pdh_query_handle) != ERROR_SUCCESS) { return OS_ERR; } query->lastUpdate = now; } return OS_OK; } template <typename QueryP> static int collect(QueryP query) { assert(query != NULL, "invariant"); return collect(&query->query); } static int formatted_counter_value(HCOUNTER counter, DWORD format, PDH_FMT_COUNTERVALU assert(value != NULL, "invariant"); return PdhDll::PdhGetFormattedCounterValue(counter, format, NULL, value) != ERROR_SUCC } static int read_counter(CounterQueryP query, DWORD format, PDH_FMT_COUNTERVALUE* const v assert(query != NULL, "invariant"); return formatted_counter_value(query->counter, format, value); } static int read_counter(MultiCounterQueryP query, int counter_idx, DWORD format, PDH_FMT assert(query != NULL, "invariant"); assert(counter_idx < query->noOfCounters, "invariant"); assert(query->counters[counter_idx] != NULL, "invariant"); return formatted_counter_value(query->counters[counter_idx], format, value); } static int read_counter(ProcessQueryP query, int counter_idx, DWORD format, PDH_FMT_COUN assert(query != NULL, "invariant"); MultiCounterQueryP const current_query = &query->set.queries[query->process_idx]; assert(current_query != NULL, "invariant"); return read_counter(current_query, counter_idx, format, value); } /* * The routine expands a process object path including a wildcard to fetch the list of process ins * having the same name, i.e. "java" or rather the value of process_image_name. * A tally of this list is returned to the caller. */ static int number_of_live_process_instances() { char* buffer = NULL; DWORD size = 0; // determine size PDH_STATUS status = PdhDll::PdhExpandWildCardPath(NULL, pdh_process_instance_wildcard_IDProcess_counter, buffer, &size, PDH_NOEXPANDCOUNTERS); while (status == PDH_MORE_DATA) { buffer = NEW_RESOURCE_ARRAY(char, size); status = PdhDll::PdhExpandWildCardPath(NULL, pdh_process_instance_wildcard_IDProcess_counter, buffer, &size, PDH_NOEXPANDCOUNTERS); } if (status != ERROR_SUCCESS) { return OS_ERR; } // count the number of live process instances int instances = 0; const char* const end = buffer + size; for (char* next = buffer; next != end && (*next != '\0'); next = &next[strlen(next) + 1], ++instances); assert(instances > 0, "invariant"); return instances; } static PDH_STATUS pdh_process_idx_to_pid(HQUERY& pdh_query_handle, int idx, LONG* p assert(pid != NULL, "invariant"); char counter_path[PDH_MAX_COUNTER_PATH]; jio_snprintf(counter_path, sizeof(counter_path) - 1, pdh_process_instance_IDProcess_ assert(strlen(counter_path) < sizeof(counter_path), "invariant"); HCOUNTER counter = NULL; PDH_STATUS status = PdhDll::PdhAddCounter(pdh_query_handle, counter_path, 0, &counter); if (status != ERROR_SUCCESS) { close_query(&pdh_query_handle, &counter); return status; } status = PdhDll::PdhCollectQueryData(pdh_query_handle); if (status != ERROR_SUCCESS) { close_query(NULL, &counter); return PDH_NO_DATA; } PDH_FMT_COUNTERVALUE counter_value; status = formatted_counter_value(counter, PDH_FMT_LONG, &counter_value); if (status != OS_OK) { close_query(&pdh_query_handle, &counter); return status; } *pid = counter_value.longValue; close_query(NULL, &counter); return ERROR_SUCCESS; } /* * Max process query index is derived from the total number of live process instances, seen * as a snap-shot at the point of initialization, i.e. processes having the same name, e.g. "java * The total number of live processes includes this process and this number - 1 is the maximum inde * to be used in a process query. */ static int max_process_query_idx = 0; /* * Working with the Process object and its related counters is inherently * problematic when using the PDH API: * * A process is not primarily identified by the process id, but by an opaque * index into a list maintained by the kernel. To distinguish which * process instance is the intended target for a query, the PDH Process API demands, * at time of registration, a string describing the target process name concatenated * with the value for this index. For example: * "\Process(java#0)", "\Process(java#1)", ... * * The bad part is that this list is constantly in-flux as * processes are exiting. One consequence is that processes with indexes * greater than the one that just terminated is now shifted down by one. * For example: * if \Process(java#1) exits, \Process(java#2) now becomes \Process(java#1), * \Process(java#2) becomes \Process(java#1) ... * * To make matters even more exciting, an already registered query is not invalidated * when the process list changes. Instead, the query will continue to work just as before, * or at least, so it seems. * Only, now, the query will read performance data from another process instance! * That's right, the performance data is now read from the process that was shifted * down by the kernel to occupy the index slot associated with our original registration. * * Solution: * The #index identifier for a Process query can only decrease after process creation. * * We therefore create an array of counter queries for all process object instances * up to and including ourselves: * * E.g. we come in as the third process instance (java#2), we then create and register * queries for the following Process object instances: * java#0, java#1, java#2 * * current_process_query_index() finds the "correct" pdh process query index by inspecting * the pdh process list, at a particular instant, i.e. just before we issue the real process query * Of course, this is an inherently racy situation because the pdh process list can change at any t * We use current_process_query_index() to help keep the number of data errors low, * where a data error is defined to be the result of using a stale index to query the wrong process. * * Ensure to call ensure_current_process_query_index() before every query involving Proces * * returns OS_ERR(-1) if anything goes wrong in the discovery process. */ static int current_process_query_index(int previous_query_idx = 0) { assert(max_process_query_idx >= 0, "invariant"); assert(max_process_query_idx >= previous_query_idx, "invariant"); assert(process_image_name != NULL, "invariant"); assert(pdh_process_instance_IDProcess_counter_fmt != NULL, "invariant"); int result = OS_ERR; HQUERY tmp_pdh_query_handle = NULL; if (open_query(&tmp_pdh_query_handle) != OS_OK) { return OS_ERR; } // We need to find the correct pdh process index corresponding to our process identifier (pid). // Begin from the index that was valid at the time of the last query. If that index is no longer vali // it means the pdh process list has changed, i.e. because other processes with the same name as u // Seek downwards to find the updated, now downshifted, list index corresponding to our pid. static const LONG current_pid = (LONG)os::current_process_id(); const int start_idx = previous_query_idx != 0 ? previous_query_idx : max_process_query_idx for (int idx = start_idx; idx >= 0; --idx) { LONG pid; const PDH_STATUS status = pdh_process_idx_to_pid(tmp_pdh_query_handle, idx, &pid); if (status == PDH_NO_DATA) { // pdh process list has changed continue; } if (status != ERROR_SUCCESS) { // something went wrong, tmp_pdh_query_handle is already closed. return OS_ERR; } if (current_pid == pid) { result = idx; break; } } close_query(&tmp_pdh_query_handle, NULL); return result; } static int ensure_current_process_query_index(ProcessQueryP query) { assert(query != NULL, "invariant"); const int previous_query_idx = query->process_idx; if (previous_query_idx == 0) { return previous_query_idx; } const int current_query_idx = current_process_query_index(previous_query_idx); if (current_query_idx == OS_ERR || current_query_idx >= query->set.size) { return OS_ERR; } if (current_query_idx == previous_query_idx) { return previous_query_idx; } assert(current_query_idx >= 0 && current_query_idx < query->set.size, "out of bounds!"); while (current_query_idx < query->set.size - 1) { const int new_size = --query->set.size; close_query(&query->set.queries[new_size]); } assert(current_query_idx < query->set.size, "invariant"); query->process_idx = current_query_idx; return OS_OK; } static MultiCounterQueryP current_process_query(ProcessQueryP query) { assert(query != NULL, "invariant"); if (ensure_current_process_query_index(query) == OS_ERR) { return NULL; } assert(query->process_idx < query->set.size, "invariant"); return &query->set.queries[query->process_idx]; } static int collect(ProcessQueryP query) { assert(query != NULL, "invariant"); MultiCounterQueryP current_query = current_process_query(query); return current_query != NULL ? collect(current_query) : OS_ERR; } /* * Construct a fully qualified PDH counter path. * * @param object_name a PDH Object string representation(required) * @param counter_name a PDH Counter string representation(required) * @param image_name a process image name string, ex. "java" (opt) * @param instance an instance string, ex. "0", "1", ... (opt) * @return the fully qualified PDH counter path. * * Caller will need a ResourceMark. * * (PdhMakeCounterPath() seems buggy on concatenating instances, hence this function instea */ static const char* make_fully_qualified_counter_path(const char* object_name, const char* counter_name, const char* image_name = NULL, const char* instance = NULL) { assert(object_name != NULL, "invariant"); assert(counter_name != NULL, "invariant"); size_t counter_path_len = strlen(object_name) + strlen(counter_name); char* counter_path; size_t jio_snprintf_result = 0; if (image_name) { /* * For paths using the "Process" Object. * * Examples: * form: "\object_name(image_name#instance)\counter_name" * actual: "\Process(java#2)\ID Process" */ counter_path_len += PROCESS_OBJECT_WITH_INSTANCES_COUNTER_FMT_LEN; counter_path_len += strlen(image_name); /* * image_name must be passed together with an associated * instance "number" ("0", "1", "2", ...). * This is required in order to create valid "Process" Object paths. * * Examples: "\Process(java#0)", \Process(java#1"), ... */ assert(instance != NULL, "invariant"); counter_path_len += strlen(instance); counter_path = NEW_RESOURCE_ARRAY(char, counter_path_len + 1); jio_snprintf_result = jio_snprintf(counter_path, counter_path_len + 1, PROCESS_OBJECT_WITH_INSTANCES_COUNTER_FMT, object_name, image_name, instance, counter_name); } else { if (instance) { /* * For paths where the Object has multiple instances. * * Examples: * form: "\object_name(instance)\counter_name" * actual: "\Processor(0)\% Privileged Time" */ counter_path_len += strlen(instance); counter_path_len += OBJECT_WITH_INSTANCES_COUNTER_FMT_LEN; } else { /* * For "normal" paths. * * Examples: * form: "\object_name\counter_name" * actual: "\Memory\Available Mbytes" */ counter_path_len += OBJECT_COUNTER_FMT_LEN; } counter_path = NEW_RESOURCE_ARRAY(char, counter_path_len + 1); if (instance) { jio_snprintf_result = jio_snprintf(counter_path, counter_path_len + 1, OBJECT_WITH_INSTANCES_COUNTER_FMT, object_name, instance, counter_name); } else { jio_snprintf_result = jio_snprintf(counter_path, counter_path_len + 1, OBJECT_COUNTER_FMT, object_name, counter_name); } } assert(counter_path_len == jio_snprintf_result, "invariant"); return counter_path; } static void log_invalid_pdh_index(DWORD index) { log_warning(os)("Unable to resolve PDH index: (%ld)", index); log_warning(os)("Please check the registry if this performance object/counter is } static bool is_valid_pdh_index(DWORD index) { DWORD dummy = 0; if (PdhDll::PdhLookupPerfNameByIndex(NULL, index, NULL, &dummy) != PDH_MORE_DATA) { log_invalid_pdh_index(index); return false; } return true; } /* * Maps an index to a resource area allocated string for the localized PDH artifact. * * Caller will need a ResourceMark. * * @param index the counter index as specified in the registry * @param p_string pointer to a char* * @return OS_OK if successful, OS_ERR on failure. */ static OSReturn lookup_name_by_index(DWORD index, char** p_string) { assert(p_string != NULL, "invariant"); if (!is_valid_pdh_index(index)) { return OS_ERR; } // determine size needed DWORD size = 0; PDH_STATUS status = PdhDll::PdhLookupPerfNameByIndex(NULL, index, NULL, &size); assert(status == PDH_MORE_DATA, "invariant"); *p_string = NEW_RESOURCE_ARRAY(char, size); if (PdhDll::PdhLookupPerfNameByIndex(NULL, index, *p_string, &size) != ERROR_SUCCESS) { return OS_ERR; } if (0 == size || *p_string == NULL) { return OS_ERR; } // windows vista does not null-terminate the string (although the docs says it will) (*p_string)[size - 1] = '\0'; return OS_OK; } static const char* copy_string_to_c_heap(const char* string) { assert(string != NULL, "invariant"); const size_t len = strlen(string); char* const cheap_allocated_string = NEW_C_HEAP_ARRAY(char, len + 1, mtInternal); strncpy(cheap_allocated_string, string, len + 1); return cheap_allocated_string; } /* * Maps a pdh artifact index to a resource area allocated string representing a localized name. * * Caller will need a ResourceMark. * * @param pdh_artifact_idx the counter index as specified in the registry * @return localized pdh artifact string if successful, NULL on failure. */ static const char* pdh_localized_artifact(DWORD pdh_artifact_idx) { char* pdh_localized_artifact_string = NULL; // get localized name for the pdh artifact idx if (lookup_name_by_index(pdh_artifact_idx, &pdh_localized_artifact_string) != OS_OK) { return NULL; } return pdh_localized_artifact_string; } /* * Returns the PDH string identifying the current process image name. * Use this prefix when getting counters from the PDH process object * representing your process. * Ex. "Process(java#0)\Virtual Bytes" - where "java" is the PDH process * image description. * * Caller needs ResourceMark. * * @return the process image string description, NULL if the call failed. */ static const char* pdh_process_image_name() { char* module_name = NEW_RESOURCE_ARRAY(char, MAX_PATH); // Find our module name and use it to extract the image name used by PDH DWORD getmfn_return = GetModuleFileName(NULL, module_name, MAX_PATH); if (getmfn_return >= MAX_PATH || 0 == getmfn_return) { return NULL; } if (os::get_last_error() == ERROR_INSUFFICIENT_BUFFER) { return NULL; } char* process_image_name = strrchr(module_name, '\\'); //drop path process_image_name++; //skip slash char* dot_pos = strrchr(process_image_name, '.'); //drop .exe dot_pos[0] = '\0'; return process_image_name; } static void deallocate_pdh_constants() { FREE_C_HEAP_ARRAY(char, process_image_name); process_image_name = NULL; FREE_C_HEAP_ARRAY(char, pdh_process_instance_IDProcess_counter_fmt); pdh_process_instance_IDProcess_counter_fmt = NULL; FREE_C_HEAP_ARRAY(char, pdh_process_instance_wildcard_IDProcess_counter); pdh_process_instance_wildcard_IDProcess_counter = NULL; } static OSReturn allocate_pdh_constants() { assert(process_image_name == NULL, "invariant"); const char* pdh_image_name = pdh_process_image_name(); if (pdh_image_name == NULL) { return OS_ERR; } process_image_name = copy_string_to_c_heap(pdh_image_name); const char* pdh_localized_process_object = pdh_localized_artifact(PDH_PROCESS_IDX); if (pdh_localized_process_object == NULL) { return OS_ERR; } const char* pdh_localized_IDProcess_counter = pdh_localized_artifact(PDH_ID_PROCESS_ if (pdh_localized_IDProcess_counter == NULL) { return OS_ERR; } const size_t id_process_base_length = strlen(process_image_name) + strlen(pdh_localized_process_object) + strlen(pdh_localized_IDProcess_counter); const size_t pdh_IDProcess_counter_fmt_len = id_process_base_length + PROCESS_OBJECT_WITH_INSTANCES_COUNTER_FMT_LEN + 2; // "%d" assert(pdh_process_instance_IDProcess_counter_fmt == NULL, "invariant"); pdh_process_instance_IDProcess_counter_fmt = NEW_C_HEAP_ARRAY(char, pdh_IDProcess_c /* "\Process(java#%d)\ID Process" */ size_t len = jio_snprintf(pdh_process_instance_IDProcess_counter_fmt, pdh_IDProcess_counter_fmt_len + 1, PROCESS_OBJECT_WITH_INSTANCES_COUNTER_FMT, pdh_localized_process_object, process_image_name, "%d", pdh_localized_IDProcess_counter); assert(pdh_process_instance_IDProcess_counter_fmt != NULL, "invariant"); assert(len == pdh_IDProcess_counter_fmt_len, "invariant"); const size_t pdh_IDProcess_wildcard_fmt_len = id_process_base_length + PROCESS_OBJECT_WITH_INSTANCES_WILDCARD_FMT_LEN; assert(pdh_process_instance_wildcard_IDProcess_counter == NULL, "invariant"); pdh_process_instance_wildcard_IDProcess_counter = NEW_C_HEAP_ARRAY(char, pdh_IDProc /* "\Process(java*)\ID Process" */ len = jio_snprintf(pdh_process_instance_wildcard_IDProcess_counter, pdh_IDProcess_wildcard_fmt_len + 1, PROCESS_OBJECT_WITH_INSTANCES_WILDCARD_FMT, pdh_localized_process_object, process_image_name, pdh_localized_IDProcess_counter); assert(pdh_process_instance_wildcard_IDProcess_counter != NULL, "invariant"); assert(len == pdh_IDProcess_wildcard_fmt_len, "invariant"); return OS_OK; } /* * Enuerate the Processor PDH object and returns a buffer containing the enumerated instances. * Caller needs ResourceMark; * * @return buffer if successful, NULL on failure. */ static const char* enumerate_cpu_instances() { char* processor; //'Processor' == PDH_PROCESSOR_IDX if (lookup_name_by_index(PDH_PROCESSOR_IDX, &processor) != OS_OK) { return NULL; } DWORD c_size = 0; DWORD i_size = 0; // enumerate all processors. PDH_STATUS pdhStat = PdhDll::PdhEnumObjectItems(NULL, // reserved NULL, // local machine processor, // object to enumerate NULL, &c_size, NULL, // instance buffer is NULL and &i_size, // pass 0 length in order to get the required size PERF_DETAIL_WIZARD, // counter detail level 0); if (PdhDll::PdhStatusFail((pdhStat))) { return NULL; } char* const instances = NEW_RESOURCE_ARRAY(char, i_size); c_size = 0; pdhStat = PdhDll::PdhEnumObjectItems(NULL, // reserved NULL, // local machine processor, // object to enumerate NULL, &c_size, instances, // now instance buffer is allocated to be filled in &i_size, // and the required size is known PERF_DETAIL_WIZARD, // counter detail level 0); return PdhDll::PdhStatusFail(pdhStat) ? NULL : instances; } static int count_logical_cpus(const char* instances) { assert(instances != NULL, "invariant"); // count logical instances. DWORD count; char* tmp; for (count = 0, tmp = const_cast<char*>(instances); *tmp != '\0'; tmp = &tmp[strlen(tmp) + 1], count++); // PDH reports an instance for each logical processor plus an instance for the total (_Total) assert(count == os::processor_count() + 1, "invalid enumeration!"); return count - 1; } static int number_of_logical_cpus() { static int numberOfCPUS = 0; if (numberOfCPUS == 0) { const char* instances = enumerate_cpu_instances(); if (instances == NULL) { return OS_ERR; } numberOfCPUS = count_logical_cpus(instances); } return numberOfCPUS; } static double cpu_factor() { static DWORD numCpus = 0; static double cpuFactor = .0; if (numCpus == 0) { numCpus = number_of_logical_cpus(); assert(os::processor_count() <= (int)numCpus, "invariant"); cpuFactor = numCpus * 100; } return cpuFactor; } static void log_error_message_on_no_PDH_artifact(const char* counter_path) { log_warning(os)("Unable to register PDH query for \"%s\"", counter_path); log_warning(os)("Please check the registry if this performance object/counter is } static int initialize_cpu_query_counters(MultiCounterQueryP query, DWORD pdh_counter_ assert(query != NULL, "invariant"); assert(query->counters != NULL, "invariant"); char* processor; //'Processor' == PDH_PROCESSOR_IDX if (lookup_name_by_index(PDH_PROCESSOR_IDX, &processor) != OS_OK) { return OS_ERR; } char* counter_name = NULL; if (lookup_name_by_index(pdh_counter_idx, &counter_name) != OS_OK) { return OS_ERR; } if (query->query.pdh_query_handle == NULL) { if (open_query(query) != OS_OK) { return OS_ERR; } } assert(query->query.pdh_query_handle != NULL, "invariant"); size_t counter_len = strlen(processor); counter_len += strlen(counter_name); counter_len += OBJECT_WITH_INSTANCES_COUNTER_FMT_LEN; // "\\%s(%s)\\%s" const char* instances = enumerate_cpu_instances(); DWORD index = 0; for (char* tmp = const_cast<char*>(instances); *tmp != '\0'; tmp = &tmp[strlen(tmp) + 1], index++) { const size_t tmp_len = strlen(tmp); char* counter_path = NEW_RESOURCE_ARRAY(char, counter_len + tmp_len + 1); const size_t jio_snprintf_result = jio_snprintf(counter_path, counter_len + tmp_len + 1, OBJECT_WITH_INSTANCES_COUNTER_FMT, processor, tmp, // instance "0", "1", .."_Total" counter_name); assert(counter_len + tmp_len == jio_snprintf_result, "invariant"); if (add_counter(query, &query->counters[index], counter_path, false) != OS_OK) { // performance counter is disabled in registry and not accessible via PerfLib log_error_message_on_no_PDH_artifact(counter_path); // return OS_OK to have the system continue to run without the missing counter return OS_OK; } } // Query once to initialize the counters which require at least two samples // (like the % CPU usage) to calculate correctly. return PdhDll::PdhCollectQueryData(query->query.pdh_query_handle) != ERROR_SUCCESS ? O } static int initialize_cpu_query(MultiCounterQueryP query) { assert(query != NULL, "invariant"); assert(!query->initialized, "invariant"); const int logical_cpu_count = number_of_logical_cpus(); assert(logical_cpu_count >= os::processor_count(), "invariant"); // we also add another counter for instance "_Total" allocate_counters(query, logical_cpu_count + 1); assert(query->noOfCounters == logical_cpu_count + 1, "invariant"); if (initialize_cpu_query_counters(query, PDH_PROCESSOR_TIME_IDX) != OS_OK) { return OS_ERR; } query->initialized = true; return OS_OK; } static int initialize_query(CounterQueryP query, DWORD pdh_object_idx, DWORD pdh_counte assert(query != NULL, "invariant"); assert(!query->initialized, "invariant"); if (!((is_valid_pdh_index(pdh_object_idx) && is_valid_pdh_index(pdh_counter_idx)))) { return OS_ERR; } const char* object = pdh_localized_artifact(pdh_object_idx); assert(object != NULL, "invariant"); const char* counter = pdh_localized_artifact(pdh_counter_idx); assert(counter != NULL, "invariant"); const char* counter_path = make_fully_qualified_counter_path(object, counter); assert(counter_path != NULL, "invariant"); if (add_counter(query, counter_path, true) != OS_OK) { return OS_ERR; } query->initialized = true; return OS_OK; } static int initialize_context_switches_query(CounterQueryP query) { return initialize_query(query, PDH_SYSTEM_IDX, PDH_CONTEXT_SWITCH_RATE_IDX); } static ProcessQueryP create_process_query() { const int current_process_query_idx = current_process_query_index(); if (current_process_query_idx == OS_ERR) { return NULL; } ProcessQueryP const query = NEW_C_HEAP_OBJ(ProcessQueryS, mtInternal); memset(query, 0, sizeof(ProcessQueryS)); query->process_idx = current_process_query_idx; const int size = current_process_query_idx + 1; query->set.queries = NEW_C_HEAP_ARRAY(MultiCounterQueryS, size, mtInternal); memset(query->set.queries, 0, sizeof(MultiCounterQueryS) * size); query->set.size = size; return query; } static int initialize_process_counter(ProcessQueryP process_query, int counter_idx, DW char* localized_process_object; if (lookup_name_by_index(PDH_PROCESS_IDX, &localized_process_object) != OS_OK) { return OS_ERR; } assert(localized_process_object != NULL, "invariant"); char* localized_counter_name; if (lookup_name_by_index(pdh_counter_idx, &localized_counter_name) != OS_OK) { return OS_ERR; } assert(localized_counter_name != NULL, "invariant"); for (int i = 0; i < process_query->set.size; ++i) { char instanceIndexBuffer[32]; const char* counter_path = make_fully_qualified_counter_path(localized_process_objec localized_counter_name, process_image_name, itoa(i, instanceIndexBuffer, 10)); assert(counter_path != NULL, "invariant"); MultiCounterQueryP const query = &process_query->set.queries[i]; if (add_counter(query, counter_idx, counter_path, true) != OS_OK) { return OS_ERR; } if (counter_idx + 1 == query->noOfCounters) { // last counter in query implies query initialized query->initialized = true; } } return OS_OK; } static int initialize_process_query(ProcessQueryP query) { assert(query != NULL, "invariant"); assert(!query->set.initialized, "invariant"); allocate_counters(query, 2); if (initialize_process_counter(query, 0, PDH_PROCESSOR_TIME_IDX) != OS_OK) { return OS_ERR; } if (initialize_process_counter(query, 1, PDH_PRIV_PROCESSOR_TIME_IDX) != OS_OK) { return OS_ERR; } query->set.initialized = true; return OS_OK; } static int reference_count = 0; static bool pdh_initialized = false; class PdhMutex : public StackObj { private: static Semaphore _semaphore; public: PdhMutex() { _semaphore.wait(); } ~PdhMutex() { _semaphore.signal(); } }; Semaphore PdhMutex::_semaphore(1); static void on_initialization_failure() { // still holder of mutex assert(max_process_query_idx == 0, "invariant"); deallocate_pdh_constants(); --reference_count; PdhDll::PdhDetach(); } static OSReturn initialize() { // still holder of mutex ResourceMark rm; if (!PdhDll::PdhAttach()) { return OS_ERR; } if (allocate_pdh_constants() != OS_OK) { on_initialization_failure(); return OS_ERR; } // Take a snapshot of the current number of live processes (including ourselves) // with the same name, e.g. "java", in order to derive a value for max_process_query_idx. const int process_instance_count = number_of_live_process_instances(); if (process_instance_count == OS_ERR) { on_initialization_failure(); return OS_ERR; } assert(process_instance_count > 0, "invariant"); max_process_query_idx = process_instance_count - 1; return OS_OK; } /* * Helper to initialize the PDH library, function pointers, constants and counters. * * Reference counting allows for unloading of pdh.dll granted all sessions use the pair: * * pdh_acquire(); * pdh_release(); * * @return OS_OK if successful, OS_ERR on failure. */ static OSReturn pdh_acquire() { PdhMutex mutex; reference_count++; if (pdh_initialized) { return OS_OK; } const OSReturn status = initialize(); pdh_initialized = status == OS_OK; return status; } static void pdh_release() { PdhMutex mutex; if (1 == reference_count--) { deallocate_pdh_constants(); PdhDll::PdhDetach(); pdh_initialized = false; } } class CPUPerformanceInterface::CPUPerformance : public CHeapObj<mtInternal> { friend class CPUPerformanceInterface; private: CounterQueryP _context_switches; ProcessQueryP _process_cpu_load; MultiCounterQueryP _machine_cpu_load; 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* jvm_user_load, double* jvm_kernel_load, double* system_t CPUPerformance(); ~CPUPerformance(); bool initialize(); }; CPUPerformanceInterface::CPUPerformance::CPUPerformance() : _context_switches(NULL bool CPUPerformanceInterface::CPUPerformance::initialize() { if (pdh_acquire() != OS_OK) { return false; } _context_switches = create_counter_query(); assert(_context_switches != NULL, "invariant"); if (initialize_context_switches_query(_context_switches) != OS_OK) { return false; } assert(_context_switches->initialized, "invariant"); _process_cpu_load = create_process_query(); if (_process_cpu_load == NULL) { return false; } if (initialize_process_query(_process_cpu_load) != OS_OK) { return false; } assert(_process_cpu_load->set.initialized, "invariant"); _machine_cpu_load = create_multi_counter_query(); assert(_machine_cpu_load != NULL, "invariant"); if (initialize_cpu_query(_machine_cpu_load) != OS_OK) { return false; } assert(_machine_cpu_load->initialized, "invariant"); return true; } CPUPerformanceInterface::CPUPerformance::~CPUPerformance() { if (_context_switches != NULL) { destroy(_context_switches); _context_switches = NULL; } if (_process_cpu_load != NULL) { destroy(_process_cpu_load); _process_cpu_load = NULL; } if (_machine_cpu_load != NULL) { destroy(_machine_cpu_load); _machine_cpu_load = NULL; } pdh_release(); } 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::context_switch_rate(double* rate) const { return _impl->context_switch_rate(rate); } int CPUPerformanceInterface::cpu_load_total_process(double* cpu_load) const { return _impl->cpu_load_total_process(cpu_load); } int CPUPerformanceInterface::cpu_loads_process(double* jvm_user_load, double* jvm_kernel_load, double* system_total_load) const { return _impl->cpu_loads_process(jvm_user_load, jvm_kernel_load, system_total_load); } int CPUPerformanceInterface::CPUPerformance::cpu_load(int which_logical_cpu, double *cpu_load = .0; if (_machine_cpu_load == NULL || !_machine_cpu_load->initialized) { return OS_ERR; } assert(which_logical_cpu < _machine_cpu_load->noOfCounters, "invariant"); if (collect(_machine_cpu_load) != OS_OK) { return OS_ERR; } // -1 is total (all cpus) const int counter_idx = -1 == which_logical_cpu ? _machine_cpu_load->noOfCounters - 1 : which PDH_FMT_COUNTERVALUE counter_value; if (read_counter(_machine_cpu_load, counter_idx, PDH_FMT_DOUBLE, &counter_value) != OS_OK) { return OS_ERR; } *cpu_load = counter_value.doubleValue / 100; return OS_OK; } int CPUPerformanceInterface::CPUPerformance::cpu_load_total_process(double* cpu_lo *cpu_load = .0; if (_process_cpu_load == NULL || !_process_cpu_load->set.initialized) { return OS_ERR; } if (collect(_process_cpu_load) != OS_OK) { return OS_ERR; } PDH_FMT_COUNTERVALUE counter_value; if (read_counter(_process_cpu_load, 0, PDH_FMT_DOUBLE | PDH_FMT_NOCAP100, &counter_value) != OS_OK return OS_ERR; } double process_load = counter_value.doubleValue / cpu_factor(); process_load = MIN2<double>(1, process_load); process_load = MAX2<double>(0, process_load); *cpu_load = process_load; return OS_OK; } int CPUPerformanceInterface::CPUPerformance::cpu_loads_process(double* jvm_user_lo double* jvm_kernel_load, double* system_total_load) { assert(jvm_user_load != NULL, "jvm_user_load is NULL!"); assert(jvm_kernel_load != NULL, "jvm_kernel_load is NULL!"); assert(system_total_load != NULL, "system_total_load is NULL!"); *jvm_user_load = .0; *jvm_kernel_load = .0; *system_total_load = .0; if (_process_cpu_load == NULL || !_process_cpu_load->set.initialized) { return OS_ERR; } if (collect(_process_cpu_load) != OS_OK) { return OS_ERR; } double process_load = .0; PDH_FMT_COUNTERVALUE counter_value; // Read PDH_PROCESSOR_TIME_IDX as counter_idx == 0 if (read_counter(_process_cpu_load, 0, PDH_FMT_DOUBLE | PDH_FMT_NOCAP100, &counter_value) != OS_OK return OS_ERR; } process_load = counter_value.doubleValue / cpu_factor(); process_load = MIN2<double>(1, process_load); process_load = MAX2<double>(0, process_load); // Read PDH_PRIV_PROCESSOR_TIME_IDX as counter_idx == 1 if (read_counter(_process_cpu_load, 1, PDH_FMT_DOUBLE | PDH_FMT_NOCAP100, &counter_value) != OS_OK return OS_ERR; } double process_kernel_load = counter_value.doubleValue / cpu_factor(); process_kernel_load = MIN2<double>(1, process_kernel_load); process_kernel_load = MAX2<double>(0, process_kernel_load); *jvm_kernel_load = process_kernel_load; double user_load = process_load - process_kernel_load; user_load = MIN2<double>(1, user_load); user_load = MAX2<double>(0, user_load); *jvm_user_load = user_load; if (collect(_machine_cpu_load) != OS_OK) { return OS_ERR; } // Read PDH_PROCESSOR_IDX as counter_idx == _machine_cpu_load->noOfCounters - 1 if (read_counter(_machine_cpu_load, _machine_cpu_load->noOfCounters - 1, PDH_FMT_DOUBL return OS_ERR; } double machine_load = counter_value.doubleValue / 100; assert(machine_load >= 0, "machine_load is negative!"); // clamp at user+system and 1.0 if (*jvm_kernel_load + *jvm_user_load > machine_load) { machine_load = MIN2(*jvm_kernel_load + *jvm_user_load, 1.0); } *system_total_load = machine_load; return OS_OK; } int CPUPerformanceInterface::CPUPerformance::context_switch_rate(double* rate) { assert(rate != NULL, "invariant"); *rate = .0; if (_context_switches == NULL || !_context_switches->initialized) { return OS_ERR; } if (collect(_context_switches) != OS_OK) { return OS_ERR; } PDH_FMT_COUNTERVALUE counter_value; if (read_counter(_context_switches, PDH_FMT_DOUBLE, &counter_value) != OS_OK) { return OS_ERR; } *rate = counter_value.doubleValue; return OS_OK; } class SystemProcessInterface::SystemProcesses : public CHeapObj<mtInternal> { friend class SystemProcessInterface; private: class ProcessIterator : public CHeapObj<mtInternal> { friend class SystemProcessInterface::SystemProcesses; private: HANDLE _hProcessSnap; PROCESSENTRY32 _pe32; BOOL _valid; char _exePath[MAX_PATH]; ProcessIterator(); ~ProcessIterator(); bool initialize(); int current(SystemProcess* const process_info); int next_process(); bool is_valid() const { return _valid != FALSE; } char* allocate_string(const char* str) const; int snapshot(); }; ProcessIterator* _iterator; SystemProcesses(); ~SystemProcesses(); bool initialize(); // information about system processes int system_processes(SystemProcess** system_processes, int* no_of_sys_processes) cons }; SystemProcessInterface::SystemProcesses::ProcessIterator::ProcessIterator() { _hProcessSnap = INVALID_HANDLE_VALUE; _valid = FALSE; _pe32.dwSize = sizeof(PROCESSENTRY32); } bool SystemProcessInterface::SystemProcesses::ProcessIterator::initialize() { return true; } int SystemProcessInterface::SystemProcesses::ProcessIterator::snapshot() { // take snapshot of all process in the system _hProcessSnap = CreateToolhelp32Snapshot(TH32CS_SNAPPROCESS, 0); if (_hProcessSnap == INVALID_HANDLE_VALUE) { return OS_ERR; } // step to first process _valid = Process32First(_hProcessSnap, &_pe32); return is_valid() ? OS_OK : OS_ERR; } SystemProcessInterface::SystemProcesses::ProcessIterator::~ProcessIterator() { if (_hProcessSnap != INVALID_HANDLE_VALUE) { CloseHandle(_hProcessSnap); } } int SystemProcessInterface::SystemProcesses::ProcessIterator::current(SystemProce assert(is_valid(), "no current process to be fetched!"); assert(process_info != NULL, "process_info is NULL!"); char* exePath = NULL; HANDLE hProcess = OpenProcess(PROCESS_QUERY_INFORMATION | PROCESS_VM_READ, false, _pe32 if (hProcess != NULL) { HMODULE hMod; DWORD cbNeeded; if (EnumProcessModules(hProcess, &hMod, sizeof(hMod), &cbNeeded) != 0) { if (GetModuleFileNameExA(hProcess, hMod, _exePath, sizeof(_exePath)) != 0) { exePath = _exePath; } } CloseHandle (hProcess); } process_info->set_pid((int)_pe32.th32ProcessID); process_info->set_name(allocate_string(_pe32.szExeFile)); process_info->set_path(allocate_string(exePath)); return OS_OK; } char* SystemProcessInterface::SystemProcesses::ProcessIterator::allocate_string(c return str != NULL ? os::strdup_check_oom(str, mtInternal) : NULL; } int SystemProcessInterface::SystemProcesses::ProcessIterator::next_process() { _valid = Process32Next(_hProcessSnap, &_pe32); return OS_OK; } SystemProcessInterface::SystemProcesses::SystemProcesses() : _iterator(NULL) {} bool SystemProcessInterface::SystemProcesses::initialize() { _iterator = new SystemProcessInterface::SystemProcesses::ProcessIterator(); return _iterator->initialize(); } SystemProcessInterface::SystemProcesses::~SystemProcesses() { if (_iterator != NULL) { delete _iterator; } } int SystemProcessInterface::SystemProcesses::system_processes(SystemProcess** syst int* no_of_sys_processes) const { assert(system_processes != NULL, "system_processes pointer is NULL!"); assert(no_of_sys_processes != NULL, "system_processes counter pointers is NULL!"); assert(_iterator != NULL, "iterator is NULL!"); // initialize pointers *no_of_sys_processes = 0; *system_processes = NULL; // take process snapshot if (_iterator->snapshot() != OS_OK) { return OS_ERR; } while (_iterator->is_valid()) { SystemProcess* tmp = new SystemProcess(); _iterator->current(tmp); //if already existing head if (*system_processes != NULL) { //move "first to second" tmp->set_next(*system_processes); } // new head *system_processes = tmp; // increment (*no_of_sys_processes)++; // step forward _iterator->next_process(); } return OS_OK; } 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(); VM_Version::initialize_cpu_information(); _cpu_info->set_number_of_hardware_threads(VM_Version::number_of_threads()); _cpu_info->set_number_of_cores(VM_Version::number_of_cores()); _cpu_info->set_number_of_sockets(VM_Version::number_of_sockets()); _cpu_info->set_cpu_name(VM_Version::cpu_name()); _cpu_info->set_cpu_description(VM_Version::cpu_description()); return true; } CPUInformationInterface::~CPUInformationInterface() { if (_cpu_info != NULL) { FREE_C_HEAP_ARRAY(char, _cpu_info->cpu_name()); _cpu_info->set_cpu_name(NULL); FREE_C_HEAP_ARRAY(char, _cpu_info->cpu_description()); _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: bool _iphlp_attached; NetworkPerformance(); NONCOPYABLE(NetworkPerformance); bool initialize(); ~NetworkPerformance(); int network_utilization(NetworkInterface** network_interfaces) const; }; NetworkPerformanceInterface::NetworkPerformance::NetworkPerformance() : _iphlp_att bool NetworkPerformanceInterface::NetworkPerformance::initialize() { _iphlp_attached = IphlpDll::IphlpAttach(); return _iphlp_attached; } NetworkPerformanceInterface::NetworkPerformance::~NetworkPerformance() { if (_iphlp_attached) { IphlpDll::IphlpDetach(); } } int NetworkPerformanceInterface::NetworkPerformance::network_utilization(NetworkI MIB_IF_TABLE2* table; if (IphlpDll::GetIfTable2(&table) != NO_ERROR) { return OS_ERR; } NetworkInterface* ret = NULL; for (ULONG i = 0; i < table->NumEntries; ++i) { if (table->Table[i].InterfaceAndOperStatusFlags.FilterInterface) { continue; } char buf[256]; if (WideCharToMultiByte(CP_UTF8, 0, table->Table[i].Description, -1, buf, sizeof(buf), N continue; } NetworkInterface* cur = new NetworkInterface(buf, table->Table[i].InOctets, table->Table ret = cur; } IphlpDll::FreeMibTable(table); *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_in return _impl->network_utilization(network_interfaces); } ¤ Dauer der Verarbeitung: 0.27 Sekunden (vorverarbeitet) ¤ |
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