replicant-frameworks_native/include/cpustats/ThreadCpuUsage.h
Glenn Kasten 542af12d10 Fix log spam about CPU frequency on one device
Previous kernels have allowed opening the CPU frequency file regardless
whether the CPU is up or not.  This fixes some log spam on one device
with dynamic hot plug CPU feature, which does not allow opening the CPU
frequency file if CPU is down.

Also, since the file descriptors are global and have long lives, add
the close-on-exec flag.

Change-Id: Ia14a2b9e20038dfb96a573920176a47a96bd3f5a
2012-05-14 16:55:26 -07:00

141 lines
6.3 KiB
C++

/*
* Copyright (C) 2011 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#ifndef _THREAD_CPU_USAGE_H
#define _THREAD_CPU_USAGE_H
#include <fcntl.h>
#include <pthread.h>
namespace android {
// Track CPU usage for the current thread.
// Units are in per-thread CPU ns, as reported by
// clock_gettime(CLOCK_THREAD_CPUTIME_ID). Simple usage: for cyclic
// threads where you want to measure the execution time of the whole
// cycle, just call sampleAndEnable() at the start of each cycle.
// For acyclic threads, or for cyclic threads where you want to measure/track
// only part of each cycle, call enable(), disable(), and/or setEnabled()
// to demarcate the region(s) of interest, and then call sample() periodically.
// This class is not thread-safe for concurrent calls from multiple threads;
// the methods of this class may only be called by the current thread
// which constructed the object.
class ThreadCpuUsage
{
public:
ThreadCpuUsage() :
mIsEnabled(false),
mWasEverEnabled(false),
mAccumulator(0),
// mPreviousTs
// mMonotonicTs
mMonotonicKnown(false)
{
(void) pthread_once(&sOnceControl, &init);
for (int i = 0; i < sKernelMax; ++i) {
mCurrentkHz[i] = (uint32_t) ~0; // unknown
}
}
~ThreadCpuUsage() { }
// Return whether currently tracking CPU usage by current thread
bool isEnabled() const { return mIsEnabled; }
// Enable tracking of CPU usage by current thread;
// any CPU used from this point forward will be tracked.
// Returns the previous enabled status.
bool enable() { return setEnabled(true); }
// Disable tracking of CPU usage by current thread;
// any CPU used from this point forward will be ignored.
// Returns the previous enabled status.
bool disable() { return setEnabled(false); }
// Set the enabled status and return the previous enabled status.
// This method is intended to be used for safe nested enable/disabling.
bool setEnabled(bool isEnabled);
// Add a sample point, and also enable tracking if needed.
// If tracking has never been enabled, then this call enables tracking but
// does _not_ add a sample -- it is not possible to add a sample the
// first time because there is no previous point to subtract from.
// Otherwise, if tracking is enabled,
// then adds a sample for tracked CPU ns since the previous
// sample, or since the first call to sampleAndEnable(), enable(), or
// setEnabled(true). If there was a previous sample but tracking is
// now disabled, then adds a sample for the tracked CPU ns accumulated
// up until the most recent disable(), resets this accumulator, and then
// enables tracking. Calling this method rather than enable() followed
// by sample() avoids a race condition for the first sample.
// Returns true if the sample 'ns' is valid, or false if invalid.
// Note that 'ns' is an output parameter passed by reference.
// The caller does not need to initialize this variable.
// The units are CPU nanoseconds consumed by current thread.
bool sampleAndEnable(double& ns);
// Add a sample point, but do not
// change the tracking enabled status. If tracking has either never been
// enabled, or has never been enabled since the last sample, then log a warning
// and don't add sample. Otherwise, adds a sample for tracked CPU ns since
// the previous sample or since the first call to sampleAndEnable(),
// enable(), or setEnabled(true) if no previous sample.
// Returns true if the sample is valid, or false if invalid.
// Note that 'ns' is an output parameter passed by reference.
// The caller does not need to initialize this variable.
// The units are CPU nanoseconds consumed by current thread.
bool sample(double& ns);
// Return the elapsed delta wall clock ns since initial enable or reset,
// as reported by clock_gettime(CLOCK_MONOTONIC).
long long elapsed() const;
// Reset elapsed wall clock. Has no effect on tracking or accumulator.
void resetElapsed();
// Return current clock frequency for specified CPU, in kHz.
// You can get your CPU number using sched_getcpu(2). Note that, unless CPU affinity
// has been configured appropriately, the CPU number can change.
// Also note that, unless the CPU governor has been configured appropriately,
// the CPU frequency can change. And even if the CPU frequency is locked down
// to a particular value, that the frequency might still be adjusted
// to prevent thermal overload. Therefore you should poll for your thread's
// current CPU number and clock frequency periodically.
uint32_t getCpukHz(int cpuNum);
private:
bool mIsEnabled; // whether tracking is currently enabled
bool mWasEverEnabled; // whether tracking was ever enabled
long long mAccumulator; // accumulated thread CPU time since last sample, in ns
struct timespec mPreviousTs; // most recent thread CPU time, valid only if mIsEnabled is true
struct timespec mMonotonicTs; // most recent monotonic time
bool mMonotonicKnown; // whether mMonotonicTs has been set
static const int MAX_CPU = 8;
static int sScalingFds[MAX_CPU];// file descriptor per CPU for reading scaling_cur_freq
uint32_t mCurrentkHz[MAX_CPU]; // current CPU frequency in kHz, not static to avoid a race
static pthread_once_t sOnceControl;
static int sKernelMax; // like MAX_CPU, but determined at runtime == cpu/kernel_max + 1
static void init(); // called once at first ThreadCpuUsage construction
static pthread_mutex_t sMutex; // protects sScalingFds[] after initialization
};
} // namespace android
#endif // _THREAD_CPU_USAGE_H