(Scroll down to The Money Shot if you just wanna know the settings to use and skip all my preamble, but be aware that you may sacrifice results if you don't understand everything fully! You've been warned!!)
The Introduction
I'm about to tell you how to get buttery smooth, lag free performance with insanely good battery life, using an old school governor featured in practically every kernel... This tweak is applicable to every phone with any ROM or kernel--stock or custom--that provides the Interactive Governor. :good:
Yeah, yeah... everyone promises good battery with great performance, but who actually delivers? Maybe it isn't as smooth as you want, or maybe it requires something your kernel or ROM don't support. Or maybe the battery life promises just aren't what you expected. There's always some awful compromise. Not here!
This isn't a guide to get 36 hour battery life... provided you never use your phone. That's deep sleep optimization, which is lovely and all, but what good is the phone if you can never use it?! I'm talking about 7-14 hour screen on, actual hands-on usage times! Without compromising anything, you can get 7-8 hour screen on usage with regular, no-compromise usage habits: daytime visible screen brightness, both radios on, sync on, network location on, all the regular usage features, the whole kit and kaboodle... all smooth as a baby's butt and snappy as a Slim Jim! (Up to 14+ hours if you can stand minimum brightness and WiFi-only! And this is with stock voltages and full frequency range--you'll likely get even more if you choose to optimize those as well!)
However, it should be noted that this does not apply to gaming, heavy camera use, etc. Anything that is an automatic battery killer in and of itself. There's nothing that can be done about anything that forces the phone to utilize its maximum resources all the time. But you should know that by now. Further, this guide is about optimizing the CPU as much as possible. It does not cover things like eliminating wakelocks so your phone sleeps well, removing unnecessary and battery draining stock apps, keeping your screen brightness down*, and all that stuff that's been covered in other posts ad infinitum. Those optimizations are up to you.
*At least on the EvoLTE, you shouldn't be turning your screen brightness above about 60%. It should be more than viewable in sunlight at that brightness, and keep in mind that the brightness power requirements increase exponentially, so a 100% bright LCD screen will use about 3.5-4.5x more power than a 60% bright screen. I don't see that fact brought up often, so I thought I'd mention it here.
The Background
I got my first Android phone (Galaxy S4) about 8 months ago, and after dropping it in the toilet a couple months ago, I had to get something cheap. Enter the EvoLTE.
Performance on the EvoLTE was not what I was used to, and that disappointed me. (I should rephrase. Performance while getting similar battery life was disappointing. What good is a fast phone if you can't use it cuz it's dead?) While I had immediately caved and ROOTed and installed a new ROM (CM 10.2), I soon pined for a new kernel with promises of overclocking, under-volting, new fangled governors, etc.
So, I S-OFFed and installed Haunted Kernel. Played with overclocking, used the suggested governor (smartmax), under-volted, all that jazz. One problem: constant reboots. My focus shifted from performance and battery to just getting it to run reliably.
To my dismay, I learned that my phone has no tolerance for overclocking, so I lost that speed boost. Further, it has no tolerance for under-volting, so I lost that power savings. And then I discovered the recommended governor (which gave pretty good battery life and so-so performance) was too buggy to be reliable, so I lost that balance.
I was never fully satisfied with the performance of that governor. It promised a lot. People raved about it. It was certainly very power-friendly and lag free, but it stuttered. Notice how everyone promises lag free, but rarely do they talk about smoothness as things slow down. You know what I mean... quick scroll through a webpage or list, and as it slows down it hops and jerks. I hate, hate, HATE that! But hey, you can't have all three--smoothness, snappiness, and stutter-free... right?
Wrong! (But I'm getting to that!)
Shifting back to stock CPU settings (clock speed and voltages) I turned my focus to the governors. Surely, I thought, one of these other fancy governors will satisfy my needs. But after weeks of tweaking and testing, I had to make a compromise in one way or another. None of them delivered the results I wanted, no matter how I tweaked them. They were better than the standard governors in many ways, but still didn't meet my expectations. I sat there, so disappointed. All these cool features to boost performance, save battery, all that... out of my reach. I was back to square one. Stock speeds, stock voltages, basic governors...
Basic governors...
...basic governors...
...basic governors..?!
Well that's something I hadn't looked into much, I thought.
I mean, why bother? Either they keep your CPU at a low clock speed, or a high one, or slowly scale between the two, or jump quickly between the two. Pretty basic stuff. The new fangled governors were designed to more efficiently finesse these brute choices to improve performance and battery life, so what would basic governors have to offer?
Nothing, I thought. Until I looked at the kernel source and realized that the Interactive Governor had some advanced features I'd never seen anyone use in their recommended settings. On any forum. Ever.
That's not to say it's some well-kept secret or that I'm the first person in the world to post about such things. But it's certainly not widely known or promoted well. Most people just jump onto some new fangled governor with default settings to provide some features that, in all honesty, we can find in a governor featured in practically all kernels, and actually may out-perform the new fangled governor in both performance and battery life!
After a bit of tweaking and experimenting, I developed some settings that provide absolutely incredible battery life, buttery smooth performance, and a lag free experience. And you don't need a fancy governor, or a custom kernel, custom clock rates, or even an EvoLTE. This will work on any ROOTed phone with the Interactive governor!
Enough long winded preamble! Let's get down to...
The Nitty Gritty
Before I lay out all the settings so you can blindly enter them into your governor control, I should to explain some of the principals I employed to get the results I did. The primary thing to understand before I do is: little might you know, the settings in the Interactive governor can be tweaked on a clock range basis. That is to say, you can finely control how the governor responds at a variety of clock rates, thus better dictating how it should operate under various loads. This is integral to the configuration, because it means the difference between jumping from the slowest speed to the highest speed under load and sustaining lower clock speeds for tasks that don't really require higher clock speeds.
By default, the Interactive governor will jump from lowest speed to a "nominal" speed under load, and then scale up from that speed as load is sustained. That is lovely, but still too twitchy to provide serious efficiency and power savings. It spends most of its time at 2 or 3 clock speeds and barely hits other clock speeds that are ideal for other tasks or usage patterns.
Instead, what we want to do is configure it to handle different types of loads in different ways. A load suited for scrolling through a webpage is not the same as a load suited for decompressing streaming video is not the same as a load suited for snappy loading of an app is not the same as a load suited for high performance gaming. Every kind of load has different tolerances at which their minimal speed is indistinguishable from their maximal speed.
To understand what's best under a variety of tasks, we have to identify two types of load profiles: nominal clock rates and efficient clock rates.
Nominal Clock Rates
Nominal clock rates are the minimum CPU clock rates that perform a given task smoothly and without stuttering or lag. To find the nominal clock rate for a given task, turn on both cores using the Performance governor and turn them both down incrementally until you find the minimum clock rate that works best for what you're trying to do, without introducing hiccups, and multiply that clock speed by your number of cores.
For example, on my EvoLTE, scrolling (not loading, simply scrolling) through a large webpage smoothly will occur when the both CPUs clock rates are no less than 432Mhz. (This is on mine without background tasks taking any CPU. Yours may be different depending on services running, the browser you use, your ROM, kernel, etc.) Because the EvoLTE has 2 cores, we multiply 432Mhz * 2 = 864Mhz. Thus, the nominal clock rate for scrolling a webpage on my EvoLTE is 864Mhz.
Now, here's the rub. If you turn off one of the cores and turn the other core to 864Mhz, you will not find that it is smooth anymore. I will not write a dissertation regarding why this is the case. Suffice it to say, despite what is often incorrectly conveyed, multi-core usage is more efficient in multi-dimensional processing loads--such as rendering graphics, playing sound, or decoding video--than a single core's performance because the time spent at a given clock rate is non-linearly less than if it were processed on a single core at a higher frequency. We want a balance of battery life and performance, and that requires using both cores. The other core will kick on when necessary to "fill in the gaps" under such a load, so our measurement stands. For our purposes, the nominal frequency for a given task is the sum of the frequencies of all cores always on at a given clock rate.
Efficient Clock Rates
Efficient clock rates are CPU clock rates that are unique in that they are the most optimal frequency given the range of voltage requirements. If you map out the frequency jump and the voltage requirement jump between each of the available clock rates, you will find that occasionally the voltage requirement will jump significantly without the frequency jumping proportionally to the previous differentials. For example, using stock voltages, the EvoLTE's msm8960 chipset clock/voltage ratios jump significantly higher from 702Mhz to 810Mhz than the ratios from 594Mhz to 702Mhz.
Using stock voltages, the EvoLTE's efficient clock rates are:
Clock Rate Biases
Using the information provided above, figure out both your nominal clock rates for the tasks you perform most often and your efficient clock rates depending on your kernel/custom voltage settings. For me, since I am using stock voltages, I use the efficient clock rates listed above. For the tasks I generally perform on my phone, my nominal clock rates are as follows:
Once you've listed all of your nominal clock rates, try to consolidate them if you have more than 3. (This is not entirely necessary as you'll see later, but it simplifies things significantly until you're more comfortable dictating more than a few clock rates for your needed task loads.) If you have any tasks that rest in the far upper portion of the frequency spectrum, discard them! We are by no means underclocking anything, but we are trying to keep the CPU clock rate as low as possible for as long as possible. However, the fastest frequencies will be available for sustained load processing, as you will see later. In my case, in addition to discarding the "high load processing", I'll sacrifice a (very) little app loading speed and consolidate video and app loading:
The Set Up
Now that we know what are the most efficient clock rates we want to focus on and what the most optimal are for what we want to do, we will start low and scale up as necessary. It's always better to begin with underperforming and tweak the settings upward until we're satisfied with the performance of our target tasks.
In its default state, the Interactive governor has a hair trigger that will raise and lower the clock rates, which means it spends too much time at unnecessary clock speeds, wasting power, and scales down too quickly, leading to stuttering performance. We will take advantage of a seldom used feature of the Interactive governor. Specifically, that with which it determines when it is okay to scale up to each higher clock rate, on a frequency by frequency basis.
We have two primary goals: respond as quickly as possible to each load request for a lag free experience and exceed the desired clock rate for a given task as little as possible. To do this, we will instruct the Interactive governor to trigger certain clock rates in different ways depending on our expected load.
I won't explain all of the settings of the Interactive governor--there are plenty of summaries all around. (Go search now if you don't know what any of the settings for Interactive governor do. I'll wait here.) However, I will explain an incredibly powerful feature of the Interactive governor that is rarely included in those summaries: multiple frequency adjustments.
The above_highspeed_delay setting, for example, defines how long the governor should wait before escalating the clock rate beyond what's set in highspeed_freq. However, you can define multiple different delays that the governor should use for any specified frequency.
For example, we want the above_highspeed_delay as low as possible to get the CPU out of the idle state as quickly as possible when a significant load is applied. However, we don't want it to jump immediately to the fastest clock rate once it's gotten out of idle, as that may be overkill for the current task. Our target trigger (which you will later adjust to suit your system and usage profile), will begin at 20000μs. That means 20,000μs (or 20ms) after our idle max load has been reached, we want to assume idle has been broken and we want to perform an actual task. (We want this value as low as possible without false positives, because it is one of a few factors that determine how snappy and lag free the CPU's response is.)
But at this point we're not ready to take on a full processing load. We may just be briefly scrolling a webpage and don't need the full power of the CPU now that we've allowed it to break out of idle. So we need it to reach a particular frequency and then hold it there again until we're sure the load is justified before we allow it to push the frequency even higher. To do that, rather than just setting
we will instead use the format "frequency:delay" to set
"Waaaait... What does that do?!"
This tells the Interactive governor to hold out 20ms after our target load when it's at our highspeed_freq (which we're actually using as our idle frequency--not a burst frequency as originally intended), but then it tells the governor to hold for 60ms after it's reached 702Mhz. (If you don't know what I'm talking about when I say "highspeed_freq" then you didn't go search for the basic Interactive governor settings and read about it! Go do that before you read any further, because I will not explain the basics of this governor!)
So now that we know how to specify different settings for different frequency ranges, let's finish it all up with...
The Money Shot
If you've made it this far, you're ready to put these strategies into play! If you have not read the previous sections, DO NOT COMPLAIN IF THE DEFAULT SETTINGS DON'T PROVIDE WHAT YOU'RE LOOKING FOR!! These settings are templates only and these need to be adjusted for each case based on your system and usage patterns! IF YOU ARE NOT GETTING THE PERFORMANCE OR BATTERY LIFE PROMISED, ***READ THE SECTIONS ABOVE!!!***
With that out of the way... let's rock!
If you are using an EvoLTE, use the following Interactive governor settings and then tweak with the instructions below:
(If you are using a phone other than an EvoLTE, you must read the above sections and replace the frequencies with your own efficient clock rates!)
Optimize Idle Frequency
Now that you've got the base configuration, we need to tweak it so that the CPU stays at your efficient idle frequency (384Mhz in this case) without spontaneously jumping when your phone is actually idle. To do this, open a CPU monitor that displays the current core frequencies (I like CoolTool, but you can use what you like as long as it doesn't significantly impact the CPU use--you're best off using a passive monitor and checking the results after 30-60 seconds of no activity), watch the frequencies and see how often they go above your efficient idle frequency when you're not doing anything at all, and adjust the following:
Enhance Task Responsiveness
Now use the efficiency and nominal clock rate correlations you made for your master clock rate list in the section above and adjust your frequencies to suit your usage patterns. For example, I had web page scrolling as my 710Mhz/864Mhz rates, so I will open a web page and scroll and see how everything feels. If it feels sluggish, I will increase all the references to "710000" in both above_highspeed_delay and target_loads upwards to the next available clock rate until that task is smooth. What you are looking for is constant poor/sluggish performance when the task you're testing for is using its highest CPU use. If the task becomes sluggish/stuttery as it winds down (such as a scrolling webpage slowing to a stop), we will address that next, so do not take that behavior into consideration as you adjust these values! If the task is smooth until (or after) it slows down, then you have reached your optimal clock rate and can move on.
If you need to exceed your nominal clock rate for a particular task, first measure it again just to be sure you had it correct. If you did indeed have it correct, leave it at your nominal clock rate and adjust the value after the colon next to the task frequency you're tuning downward in increments of 5. For example, if my setting of "864000:80" is still not sufficient, I will adjust it first to "864000:75", then "864000:70", and so on until the task is smooth. However, it almost certainly won't come to this, but if you reach ":50" and the task still isn't performing how you want, set it back to ":80" and increase the clock step once more, then decrease the ":80" until it is smooth.
Do the same for each other frequency in your master clock rate list until you are satisfied. If you have chosen to use more than 2 primary clock rates, add them and use ":##" values between the two surrounding frequency values.
Fix Stuttering
Now that you have adjusted your frequencies for optimal high CPU use in each given task, you may notice some stuttering as the task winds down. (Such as a scrolling webpage slowing to a stop.) If this bothers you, you can tweak this at the expense of some (minor) battery life by adjusting min_sample_time up in increments of 5000 until you are satisfied.
If you have exceeded a value of 100000 for the min_sample_time setting and still are not satisfied, change it back to 40000 and increase (and re-optimize) your idle frequency by one step. This will impact battery life more, but less than if you were to keep increasing the value of min_sample_time.
Adjust High Load Clock Rates
You're almost done! Now you can leave everything as is and be satisfied with your amazing, buttery smooth, snappy experience, or you can optionally tweak things further to either increase the responsiveness of high load tasks (such as loading image previews in Gallery) or increase battery life somewhat.
Adjust the final delay value in above_highspeed_delay to suit your needs. The default ("150000") means that the CPU load at the highest set frequency (default "1026000") will have to be sustained for 150ms before it allows the load to go above that frequency. Increasing this value will prevent the CPU from reaching higher frequencies (which may be unnecessary) as often, saving battery life. This will come at the expense of burst-type high CPU load tasks. Reducing it will allow the CPU to reach higher frequencies more often, at the expense of battery life. However, adjusting this is probably unnecessary, as it will most likely not yield any perceptible difference in performance. It is recommended to leave this value at its default.
The Conclusion
I have achieved unprecedented performance, smoothness, snappiness, and battery life with the default settings I outlined above. However, your mileage may vary, as every phone, ROM, kernel, installed applications, etc are different. This is a very sensitive governor profile and must be tweaked to just meet the requirements of your system and your usage patterns!
If it is not optimally tuned, performance and battery life will suffer! If you're not seeing buttery smooth, snappy performance, you have not correctly tuned it for your system!! However, if you do have superb performance (and you tweaked the values conservatively and not in large steps), then you will also get the aforementioned battery life.
I will be happy to answer any questions, or provide any guidance I can. However:
The Introduction
I'm about to tell you how to get buttery smooth, lag free performance with insanely good battery life, using an old school governor featured in practically every kernel... This tweak is applicable to every phone with any ROM or kernel--stock or custom--that provides the Interactive Governor. :good:
Yeah, yeah... everyone promises good battery with great performance, but who actually delivers? Maybe it isn't as smooth as you want, or maybe it requires something your kernel or ROM don't support. Or maybe the battery life promises just aren't what you expected. There's always some awful compromise. Not here!
This isn't a guide to get 36 hour battery life... provided you never use your phone. That's deep sleep optimization, which is lovely and all, but what good is the phone if you can never use it?! I'm talking about 7-14 hour screen on, actual hands-on usage times! Without compromising anything, you can get 7-8 hour screen on usage with regular, no-compromise usage habits: daytime visible screen brightness, both radios on, sync on, network location on, all the regular usage features, the whole kit and kaboodle... all smooth as a baby's butt and snappy as a Slim Jim! (Up to 14+ hours if you can stand minimum brightness and WiFi-only! And this is with stock voltages and full frequency range--you'll likely get even more if you choose to optimize those as well!)
However, it should be noted that this does not apply to gaming, heavy camera use, etc. Anything that is an automatic battery killer in and of itself. There's nothing that can be done about anything that forces the phone to utilize its maximum resources all the time. But you should know that by now. Further, this guide is about optimizing the CPU as much as possible. It does not cover things like eliminating wakelocks so your phone sleeps well, removing unnecessary and battery draining stock apps, keeping your screen brightness down*, and all that stuff that's been covered in other posts ad infinitum. Those optimizations are up to you.
*At least on the EvoLTE, you shouldn't be turning your screen brightness above about 60%. It should be more than viewable in sunlight at that brightness, and keep in mind that the brightness power requirements increase exponentially, so a 100% bright LCD screen will use about 3.5-4.5x more power than a 60% bright screen. I don't see that fact brought up often, so I thought I'd mention it here.
The Background
I got my first Android phone (Galaxy S4) about 8 months ago, and after dropping it in the toilet a couple months ago, I had to get something cheap. Enter the EvoLTE.
Performance on the EvoLTE was not what I was used to, and that disappointed me. (I should rephrase. Performance while getting similar battery life was disappointing. What good is a fast phone if you can't use it cuz it's dead?) While I had immediately caved and ROOTed and installed a new ROM (CM 10.2), I soon pined for a new kernel with promises of overclocking, under-volting, new fangled governors, etc.
So, I S-OFFed and installed Haunted Kernel. Played with overclocking, used the suggested governor (smartmax), under-volted, all that jazz. One problem: constant reboots. My focus shifted from performance and battery to just getting it to run reliably.
To my dismay, I learned that my phone has no tolerance for overclocking, so I lost that speed boost. Further, it has no tolerance for under-volting, so I lost that power savings. And then I discovered the recommended governor (which gave pretty good battery life and so-so performance) was too buggy to be reliable, so I lost that balance.
I was never fully satisfied with the performance of that governor. It promised a lot. People raved about it. It was certainly very power-friendly and lag free, but it stuttered. Notice how everyone promises lag free, but rarely do they talk about smoothness as things slow down. You know what I mean... quick scroll through a webpage or list, and as it slows down it hops and jerks. I hate, hate, HATE that! But hey, you can't have all three--smoothness, snappiness, and stutter-free... right?
Wrong! (But I'm getting to that!)
Shifting back to stock CPU settings (clock speed and voltages) I turned my focus to the governors. Surely, I thought, one of these other fancy governors will satisfy my needs. But after weeks of tweaking and testing, I had to make a compromise in one way or another. None of them delivered the results I wanted, no matter how I tweaked them. They were better than the standard governors in many ways, but still didn't meet my expectations. I sat there, so disappointed. All these cool features to boost performance, save battery, all that... out of my reach. I was back to square one. Stock speeds, stock voltages, basic governors...
Basic governors...
...basic governors...
...basic governors..?!
Well that's something I hadn't looked into much, I thought.
I mean, why bother? Either they keep your CPU at a low clock speed, or a high one, or slowly scale between the two, or jump quickly between the two. Pretty basic stuff. The new fangled governors were designed to more efficiently finesse these brute choices to improve performance and battery life, so what would basic governors have to offer?
Nothing, I thought. Until I looked at the kernel source and realized that the Interactive Governor had some advanced features I'd never seen anyone use in their recommended settings. On any forum. Ever.
That's not to say it's some well-kept secret or that I'm the first person in the world to post about such things. But it's certainly not widely known or promoted well. Most people just jump onto some new fangled governor with default settings to provide some features that, in all honesty, we can find in a governor featured in practically all kernels, and actually may out-perform the new fangled governor in both performance and battery life!
After a bit of tweaking and experimenting, I developed some settings that provide absolutely incredible battery life, buttery smooth performance, and a lag free experience. And you don't need a fancy governor, or a custom kernel, custom clock rates, or even an EvoLTE. This will work on any ROOTed phone with the Interactive governor!
Enough long winded preamble! Let's get down to...
The Nitty Gritty
Before I lay out all the settings so you can blindly enter them into your governor control, I should to explain some of the principals I employed to get the results I did. The primary thing to understand before I do is: little might you know, the settings in the Interactive governor can be tweaked on a clock range basis. That is to say, you can finely control how the governor responds at a variety of clock rates, thus better dictating how it should operate under various loads. This is integral to the configuration, because it means the difference between jumping from the slowest speed to the highest speed under load and sustaining lower clock speeds for tasks that don't really require higher clock speeds.
By default, the Interactive governor will jump from lowest speed to a "nominal" speed under load, and then scale up from that speed as load is sustained. That is lovely, but still too twitchy to provide serious efficiency and power savings. It spends most of its time at 2 or 3 clock speeds and barely hits other clock speeds that are ideal for other tasks or usage patterns.
Instead, what we want to do is configure it to handle different types of loads in different ways. A load suited for scrolling through a webpage is not the same as a load suited for decompressing streaming video is not the same as a load suited for snappy loading of an app is not the same as a load suited for high performance gaming. Every kind of load has different tolerances at which their minimal speed is indistinguishable from their maximal speed.
To understand what's best under a variety of tasks, we have to identify two types of load profiles: nominal clock rates and efficient clock rates.
Nominal Clock Rates
Nominal clock rates are the minimum CPU clock rates that perform a given task smoothly and without stuttering or lag. To find the nominal clock rate for a given task, turn on both cores using the Performance governor and turn them both down incrementally until you find the minimum clock rate that works best for what you're trying to do, without introducing hiccups, and multiply that clock speed by your number of cores.
For example, on my EvoLTE, scrolling (not loading, simply scrolling) through a large webpage smoothly will occur when the both CPUs clock rates are no less than 432Mhz. (This is on mine without background tasks taking any CPU. Yours may be different depending on services running, the browser you use, your ROM, kernel, etc.) Because the EvoLTE has 2 cores, we multiply 432Mhz * 2 = 864Mhz. Thus, the nominal clock rate for scrolling a webpage on my EvoLTE is 864Mhz.
Now, here's the rub. If you turn off one of the cores and turn the other core to 864Mhz, you will not find that it is smooth anymore. I will not write a dissertation regarding why this is the case. Suffice it to say, despite what is often incorrectly conveyed, multi-core usage is more efficient in multi-dimensional processing loads--such as rendering graphics, playing sound, or decoding video--than a single core's performance because the time spent at a given clock rate is non-linearly less than if it were processed on a single core at a higher frequency. We want a balance of battery life and performance, and that requires using both cores. The other core will kick on when necessary to "fill in the gaps" under such a load, so our measurement stands. For our purposes, the nominal frequency for a given task is the sum of the frequencies of all cores always on at a given clock rate.
Efficient Clock Rates
Efficient clock rates are CPU clock rates that are unique in that they are the most optimal frequency given the range of voltage requirements. If you map out the frequency jump and the voltage requirement jump between each of the available clock rates, you will find that occasionally the voltage requirement will jump significantly without the frequency jumping proportionally to the previous differentials. For example, using stock voltages, the EvoLTE's msm8960 chipset clock/voltage ratios jump significantly higher from 702Mhz to 810Mhz than the ratios from 594Mhz to 702Mhz.
Using stock voltages, the EvoLTE's efficient clock rates are:
- 384Mhz
- 702Mhz
- 1026Mhz
- 1512Mhz
Clock Rate Biases
Using the information provided above, figure out both your nominal clock rates for the tasks you perform most often and your efficient clock rates depending on your kernel/custom voltage settings. For me, since I am using stock voltages, I use the efficient clock rates listed above. For the tasks I generally perform on my phone, my nominal clock rates are as follows:
- Idle - 189Mhz
- Page Scrolling - 864Mhz
- Video - 1134Mhz
- App Loading - 1350Mhz
- High Load Processing - 1512Mhz
Once you've listed all of your nominal clock rates, try to consolidate them if you have more than 3. (This is not entirely necessary as you'll see later, but it simplifies things significantly until you're more comfortable dictating more than a few clock rates for your needed task loads.) If you have any tasks that rest in the far upper portion of the frequency spectrum, discard them! We are by no means underclocking anything, but we are trying to keep the CPU clock rate as low as possible for as long as possible. However, the fastest frequencies will be available for sustained load processing, as you will see later. In my case, in addition to discarding the "high load processing", I'll sacrifice a (very) little app loading speed and consolidate video and app loading:
- Idle - 189Mhz
- Page Scrolling - 864Mhz
- Video/App Loading - 1134Mhz
- Idle - 189Mhz efficient / 189Mhz nominal
- Page Scrolling - 710Mhz efficient / 864Mhz nominal
- Video/App Loading - 1026Mhz efficient / 1134Mhz nominal
The Set Up
Now that we know what are the most efficient clock rates we want to focus on and what the most optimal are for what we want to do, we will start low and scale up as necessary. It's always better to begin with underperforming and tweak the settings upward until we're satisfied with the performance of our target tasks.
In its default state, the Interactive governor has a hair trigger that will raise and lower the clock rates, which means it spends too much time at unnecessary clock speeds, wasting power, and scales down too quickly, leading to stuttering performance. We will take advantage of a seldom used feature of the Interactive governor. Specifically, that with which it determines when it is okay to scale up to each higher clock rate, on a frequency by frequency basis.
We have two primary goals: respond as quickly as possible to each load request for a lag free experience and exceed the desired clock rate for a given task as little as possible. To do this, we will instruct the Interactive governor to trigger certain clock rates in different ways depending on our expected load.
I won't explain all of the settings of the Interactive governor--there are plenty of summaries all around. (Go search now if you don't know what any of the settings for Interactive governor do. I'll wait here.) However, I will explain an incredibly powerful feature of the Interactive governor that is rarely included in those summaries: multiple frequency adjustments.
The above_highspeed_delay setting, for example, defines how long the governor should wait before escalating the clock rate beyond what's set in highspeed_freq. However, you can define multiple different delays that the governor should use for any specified frequency.
For example, we want the above_highspeed_delay as low as possible to get the CPU out of the idle state as quickly as possible when a significant load is applied. However, we don't want it to jump immediately to the fastest clock rate once it's gotten out of idle, as that may be overkill for the current task. Our target trigger (which you will later adjust to suit your system and usage profile), will begin at 20000μs. That means 20,000μs (or 20ms) after our idle max load has been reached, we want to assume idle has been broken and we want to perform an actual task. (We want this value as low as possible without false positives, because it is one of a few factors that determine how snappy and lag free the CPU's response is.)
But at this point we're not ready to take on a full processing load. We may just be briefly scrolling a webpage and don't need the full power of the CPU now that we've allowed it to break out of idle. So we need it to reach a particular frequency and then hold it there again until we're sure the load is justified before we allow it to push the frequency even higher. To do that, rather than just setting
above_highspeed_delay - 20000
we will instead use the format "frequency:delay" to set
above_highspeed_delay - 20000 702000:60000
"Waaaait... What does that do?!"
This tells the Interactive governor to hold out 20ms after our target load when it's at our highspeed_freq (which we're actually using as our idle frequency--not a burst frequency as originally intended), but then it tells the governor to hold for 60ms after it's reached 702Mhz. (If you don't know what I'm talking about when I say "highspeed_freq" then you didn't go search for the basic Interactive governor settings and read about it! Go do that before you read any further, because I will not explain the basics of this governor!)
So now that we know how to specify different settings for different frequency ranges, let's finish it all up with...
The Money Shot
If you've made it this far, you're ready to put these strategies into play! If you have not read the previous sections, DO NOT COMPLAIN IF THE DEFAULT SETTINGS DON'T PROVIDE WHAT YOU'RE LOOKING FOR!! These settings are templates only and these need to be adjusted for each case based on your system and usage patterns! IF YOU ARE NOT GETTING THE PERFORMANCE OR BATTERY LIFE PROMISED, ***READ THE SECTIONS ABOVE!!!***
With that out of the way... let's rock!
If you are using an EvoLTE, use the following Interactive governor settings and then tweak with the instructions below:
(If you are using a phone other than an EvoLTE, you must read the above sections and replace the frequencies with your own efficient clock rates!)
- above_highspeed_delay - 20000 702000:60000 1026000:150000
- boost - 0
- boostpulse_duration - 80000
- go_highspeed_load - 99
- hispeed_freq - 384000
- io_is_busy - 0
- min_sample_time - 40000
- target_loads - 98 384000:40 702000:80 1026000:95
- timer_rate - 30000
- timer_slack - 80000
Optimize Idle Frequency
Now that you've got the base configuration, we need to tweak it so that the CPU stays at your efficient idle frequency (384Mhz in this case) without spontaneously jumping when your phone is actually idle. To do this, open a CPU monitor that displays the current core frequencies (I like CoolTool, but you can use what you like as long as it doesn't significantly impact the CPU use--you're best off using a passive monitor and checking the results after 30-60 seconds of no activity), watch the frequencies and see how often they go above your efficient idle frequency when you're not doing anything at all, and adjust the following:
- timer_rate - If your idle frequency is not being exceeded much, adjust this downward in increments of 5000 until it is, then increase it by 5000. If your idle frequency is being exceeded often, adjust this upward in increments of 5000 until your CPU primarily stays at or below your desired idle frequency.
- above_highspeed_delay - Only if your timer_rate has matched or exceeded 50000 and still won't stay at or below your desired idle frequency most of the time, set timer_rate to 50000 and adjust the "20000" portion of the value upwards in increments of 5000 until the idle frequency has stabilized.
Enhance Task Responsiveness
Now use the efficiency and nominal clock rate correlations you made for your master clock rate list in the section above and adjust your frequencies to suit your usage patterns. For example, I had web page scrolling as my 710Mhz/864Mhz rates, so I will open a web page and scroll and see how everything feels. If it feels sluggish, I will increase all the references to "710000" in both above_highspeed_delay and target_loads upwards to the next available clock rate until that task is smooth. What you are looking for is constant poor/sluggish performance when the task you're testing for is using its highest CPU use. If the task becomes sluggish/stuttery as it winds down (such as a scrolling webpage slowing to a stop), we will address that next, so do not take that behavior into consideration as you adjust these values! If the task is smooth until (or after) it slows down, then you have reached your optimal clock rate and can move on.
If you need to exceed your nominal clock rate for a particular task, first measure it again just to be sure you had it correct. If you did indeed have it correct, leave it at your nominal clock rate and adjust the value after the colon next to the task frequency you're tuning downward in increments of 5. For example, if my setting of "864000:80" is still not sufficient, I will adjust it first to "864000:75", then "864000:70", and so on until the task is smooth. However, it almost certainly won't come to this, but if you reach ":50" and the task still isn't performing how you want, set it back to ":80" and increase the clock step once more, then decrease the ":80" until it is smooth.
Do the same for each other frequency in your master clock rate list until you are satisfied. If you have chosen to use more than 2 primary clock rates, add them and use ":##" values between the two surrounding frequency values.
Fix Stuttering
Now that you have adjusted your frequencies for optimal high CPU use in each given task, you may notice some stuttering as the task winds down. (Such as a scrolling webpage slowing to a stop.) If this bothers you, you can tweak this at the expense of some (minor) battery life by adjusting min_sample_time up in increments of 5000 until you are satisfied.
If you have exceeded a value of 100000 for the min_sample_time setting and still are not satisfied, change it back to 40000 and increase (and re-optimize) your idle frequency by one step. This will impact battery life more, but less than if you were to keep increasing the value of min_sample_time.
Adjust High Load Clock Rates
You're almost done! Now you can leave everything as is and be satisfied with your amazing, buttery smooth, snappy experience, or you can optionally tweak things further to either increase the responsiveness of high load tasks (such as loading image previews in Gallery) or increase battery life somewhat.
Adjust the final delay value in above_highspeed_delay to suit your needs. The default ("150000") means that the CPU load at the highest set frequency (default "1026000") will have to be sustained for 150ms before it allows the load to go above that frequency. Increasing this value will prevent the CPU from reaching higher frequencies (which may be unnecessary) as often, saving battery life. This will come at the expense of burst-type high CPU load tasks. Reducing it will allow the CPU to reach higher frequencies more often, at the expense of battery life. However, adjusting this is probably unnecessary, as it will most likely not yield any perceptible difference in performance. It is recommended to leave this value at its default.
The Conclusion
I have achieved unprecedented performance, smoothness, snappiness, and battery life with the default settings I outlined above. However, your mileage may vary, as every phone, ROM, kernel, installed applications, etc are different. This is a very sensitive governor profile and must be tweaked to just meet the requirements of your system and your usage patterns!
If it is not optimally tuned, performance and battery life will suffer! If you're not seeing buttery smooth, snappy performance, you have not correctly tuned it for your system!! However, if you do have superb performance (and you tweaked the values conservatively and not in large steps), then you will also get the aforementioned battery life.
I will be happy to answer any questions, or provide any guidance I can. However:
- You must otherwise optimize your phone first! This will not "fix" a poorly optimized system and will, in fact, reduce performance and battery life without further optimization and proper tweaking.
- I will not answer questions about "what is a governor?" There are plenty of resources available already, so search for them.
- I will not answer questions about "how can I tweak [some other] governor?" This is about the Interactive governor only.
- I will not respond to "nuh uh! show proof!" posts. The fact that I spent 12 hours writing this up should be proof enough that I am satisfied with the results. You can take it or leave it; makes no difference to me. The default settings should work with any fully optimized EvoLTE, so just try them on your own. If you're not absolutely satisfied (and trust me, either it'll work out-of-the-box with flying colors and you'll know it works for your system, or it'll be an awful experience which means you must tweak it), then you haven't adequately adjusted the settings to suit your system.
