replicant-frameworks_native/include/cpustats/ThreadCpuUsage.h

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/*
* 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();
};
} // namespace android
#endif // _THREAD_CPU_USAGE_H