// Copyright 2013 The Chromium Authors // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "base/process/process_metrics.h" #include // Must be in front of other Windows header files. #include #include #include #include #include #include "base/logging.h" #include "base/memory/ptr_util.h" #include "base/notreached.h" #include "base/process/process_metrics_iocounters.h" #include "base/system/sys_info.h" #include "base/threading/scoped_blocking_call.h" #include "base/values.h" #include "build/build_config.h" namespace base { namespace { // ntstatus.h conflicts with windows.h so define this locally. #define STATUS_SUCCESS ((NTSTATUS)0x00000000L) // Definition of this struct is taken from the book: // Windows NT/200, Native API reference, Gary Nebbett struct SYSTEM_PERFORMANCE_INFORMATION { // Total idle time of all processes in the system (units of 100 ns). LARGE_INTEGER IdleTime; // Number of bytes read (by all call to ZwReadFile). LARGE_INTEGER ReadTransferCount; // Number of bytes written (by all call to ZwWriteFile). LARGE_INTEGER WriteTransferCount; // Number of bytes transferred (e.g. DeviceIoControlFile) LARGE_INTEGER OtherTransferCount; // The amount of read operations. ULONG ReadOperationCount; // The amount of write operations. ULONG WriteOperationCount; // The amount of other operations. ULONG OtherOperationCount; // The number of pages of physical memory available to processes running on // the system. ULONG AvailablePages; ULONG TotalCommittedPages; ULONG TotalCommitLimit; ULONG PeakCommitment; ULONG PageFaults; ULONG WriteCopyFaults; ULONG TransitionFaults; ULONG CacheTransitionFaults; ULONG DemandZeroFaults; // The number of pages read from disk to resolve page faults. ULONG PagesRead; // The number of read operations initiated to resolve page faults. ULONG PageReadIos; ULONG CacheReads; ULONG CacheIos; // The number of pages written to the system's pagefiles. ULONG PagefilePagesWritten; // The number of write operations performed on the system's pagefiles. ULONG PagefilePageWriteIos; ULONG MappedFilePagesWritten; ULONG MappedFilePageWriteIos; ULONG PagedPoolUsage; ULONG NonPagedPoolUsage; ULONG PagedPoolAllocs; ULONG PagedPoolFrees; ULONG NonPagedPoolAllocs; ULONG NonPagedPoolFrees; ULONG TotalFreeSystemPtes; ULONG SystemCodePage; ULONG TotalSystemDriverPages; ULONG TotalSystemCodePages; ULONG SmallNonPagedLookasideListAllocateHits; ULONG SmallPagedLookasideListAllocateHits; ULONG Reserved3; ULONG MmSystemCachePage; ULONG PagedPoolPage; ULONG SystemDriverPage; ULONG FastReadNoWait; ULONG FastReadWait; ULONG FastReadResourceMiss; ULONG FastReadNotPossible; ULONG FastMdlReadNoWait; ULONG FastMdlReadWait; ULONG FastMdlReadResourceMiss; ULONG FastMdlReadNotPossible; ULONG MapDataNoWait; ULONG MapDataWait; ULONG MapDataNoWaitMiss; ULONG MapDataWaitMiss; ULONG PinMappedDataCount; ULONG PinReadNoWait; ULONG PinReadWait; ULONG PinReadNoWaitMiss; ULONG PinReadWaitMiss; ULONG CopyReadNoWait; ULONG CopyReadWait; ULONG CopyReadNoWaitMiss; ULONG CopyReadWaitMiss; ULONG MdlReadNoWait; ULONG MdlReadWait; ULONG MdlReadNoWaitMiss; ULONG MdlReadWaitMiss; ULONG ReadAheadIos; ULONG LazyWriteIos; ULONG LazyWritePages; ULONG DataFlushes; ULONG DataPages; ULONG ContextSwitches; ULONG FirstLevelTbFills; ULONG SecondLevelTbFills; ULONG SystemCalls; }; } // namespace size_t GetMaxFds() { // Windows is only limited by the amount of physical memory. return std::numeric_limits::max(); } size_t GetHandleLimit() { // Rounded down from value reported here: // http://blogs.technet.com/b/markrussinovich/archive/2009/09/29/3283844.aspx return static_cast(1 << 23); } // static std::unique_ptr ProcessMetrics::CreateProcessMetrics( ProcessHandle process) { return WrapUnique(new ProcessMetrics(process)); } TimeDelta ProcessMetrics::GetCumulativeCPUUsage() { FILETIME creation_time; FILETIME exit_time; FILETIME kernel_time; FILETIME user_time; if (!process_.is_valid()) return TimeDelta(); if (!GetProcessTimes(process_.get(), &creation_time, &exit_time, &kernel_time, &user_time)) { // This should never fail because we duplicate the handle to guarantee it // will remain valid. DCHECK(false); return TimeDelta(); } return TimeDelta::FromFileTime(kernel_time) + TimeDelta::FromFileTime(user_time); } TimeDelta ProcessMetrics::GetPreciseCumulativeCPUUsage() { #if defined(ARCH_CPU_ARM64) // Precise CPU usage is not available on Arm CPUs because they don't support // constant rate TSC. return GetCumulativeCPUUsage(); #else // !defined(ARCH_CPU_ARM64) if (!time_internal::HasConstantRateTSC()) return GetCumulativeCPUUsage(); const double tsc_ticks_per_second = time_internal::TSCTicksPerSecond(); if (tsc_ticks_per_second == 0) { // TSC is only initialized once TSCTicksPerSecond() is called twice 50 ms // apart on the same thread to get a baseline. This often doesn't happen in // unit tests, and theoretically may happen in production if // GetPreciseCumulativeCPUUsage() is called before any uses of ThreadTicks. return GetCumulativeCPUUsage(); } ULONG64 process_cycle_time = 0; if (!QueryProcessCycleTime(process_.get(), &process_cycle_time)) { NOTREACHED(); return TimeDelta(); } const double process_time_seconds = process_cycle_time / tsc_ticks_per_second; return Seconds(process_time_seconds); #endif // !defined(ARCH_CPU_ARM64) } bool ProcessMetrics::GetIOCounters(IoCounters* io_counters) const { if (!process_.is_valid()) return false; return GetProcessIoCounters(process_.get(), io_counters) != FALSE; } uint64_t ProcessMetrics::GetCumulativeDiskUsageInBytes() { IoCounters counters; if (!GetIOCounters(&counters)) return 0; return counters.ReadTransferCount + counters.WriteTransferCount + counters.OtherTransferCount; } ProcessMetrics::ProcessMetrics(ProcessHandle process) { if (process) { HANDLE duplicate_handle = INVALID_HANDLE_VALUE; BOOL result = ::DuplicateHandle(::GetCurrentProcess(), process, ::GetCurrentProcess(), &duplicate_handle, PROCESS_QUERY_INFORMATION, FALSE, 0); DPCHECK(result); process_.Set(duplicate_handle); } } size_t GetSystemCommitCharge() { // Get the System Page Size. SYSTEM_INFO system_info; GetSystemInfo(&system_info); PERFORMANCE_INFORMATION info; if (!GetPerformanceInfo(&info, sizeof(info))) { DLOG(ERROR) << "Failed to fetch internal performance info."; return 0; } return (info.CommitTotal * system_info.dwPageSize) / 1024; } // This function uses the following mapping between MEMORYSTATUSEX and // SystemMemoryInfoKB: // ullTotalPhys ==> total // ullAvailPhys ==> avail_phys // ullTotalPageFile ==> swap_total // ullAvailPageFile ==> swap_free bool GetSystemMemoryInfo(SystemMemoryInfoKB* meminfo) { MEMORYSTATUSEX mem_status; mem_status.dwLength = sizeof(mem_status); if (!::GlobalMemoryStatusEx(&mem_status)) return false; meminfo->total = saturated_cast(mem_status.ullTotalPhys / 1024); meminfo->avail_phys = saturated_cast(mem_status.ullAvailPhys / 1024); meminfo->swap_total = saturated_cast(mem_status.ullTotalPageFile / 1024); meminfo->swap_free = saturated_cast(mem_status.ullAvailPageFile / 1024); return true; } size_t ProcessMetrics::GetMallocUsage() { // Unsupported as getting malloc usage on Windows requires iterating through // the heap which is slow and crashes. return 0; } SystemPerformanceInfo::SystemPerformanceInfo() = default; SystemPerformanceInfo::SystemPerformanceInfo( const SystemPerformanceInfo& other) = default; SystemPerformanceInfo& SystemPerformanceInfo::operator=( const SystemPerformanceInfo& other) = default; Value::Dict SystemPerformanceInfo::ToDict() const { Value::Dict result; // Write out uint64_t variables as doubles. // Note: this may discard some precision, but for JS there's no other option. result.Set("idle_time", strict_cast(idle_time)); result.Set("read_transfer_count", strict_cast(read_transfer_count)); result.Set("write_transfer_count", strict_cast(write_transfer_count)); result.Set("other_transfer_count", strict_cast(other_transfer_count)); result.Set("read_operation_count", strict_cast(read_operation_count)); result.Set("write_operation_count", strict_cast(write_operation_count)); result.Set("other_operation_count", strict_cast(other_operation_count)); result.Set("pagefile_pages_written", strict_cast(pagefile_pages_written)); result.Set("pagefile_pages_write_ios", strict_cast(pagefile_pages_write_ios)); result.Set("available_pages", strict_cast(available_pages)); result.Set("pages_read", strict_cast(pages_read)); result.Set("page_read_ios", strict_cast(page_read_ios)); return result; } // Retrieves performance counters from the operating system. // Fills in the provided |info| structure. Returns true on success. BASE_EXPORT bool GetSystemPerformanceInfo(SystemPerformanceInfo* info) { SYSTEM_PERFORMANCE_INFORMATION counters = {}; { // The call to NtQuerySystemInformation might block on a lock. base::ScopedBlockingCall scoped_blocking_call(FROM_HERE, BlockingType::MAY_BLOCK); if (::NtQuerySystemInformation(::SystemPerformanceInformation, &counters, sizeof(SYSTEM_PERFORMANCE_INFORMATION), nullptr) != STATUS_SUCCESS) { return false; } } info->idle_time = static_cast(counters.IdleTime.QuadPart); info->read_transfer_count = static_cast(counters.ReadTransferCount.QuadPart); info->write_transfer_count = static_cast(counters.WriteTransferCount.QuadPart); info->other_transfer_count = static_cast(counters.OtherTransferCount.QuadPart); info->read_operation_count = counters.ReadOperationCount; info->write_operation_count = counters.WriteOperationCount; info->other_operation_count = counters.OtherOperationCount; info->pagefile_pages_written = counters.PagefilePagesWritten; info->pagefile_pages_write_ios = counters.PagefilePageWriteIos; info->available_pages = counters.AvailablePages; info->pages_read = counters.PagesRead; info->page_read_ios = counters.PageReadIos; return true; } } // namespace base