Develop Bugs

Governors explained

Found this in EVO 4G section, thought I would share.
CPU Governors explained
Thanks to deedii for posting this in another forum:
http://forum.xda-developers.com/show...65&postcount=2
Android CPU governors explained
What is a governor?
A governor is a driver for the regulation of CPUFreq - CPU frequency. As the name suggests, we, the Governor of the decision, when at full capacity, the MaxFreq - will be achieved or how fast the minFreq - - maximum frequency is reached minimum frequency or center frequency. He decides when, how and how long the CPU and still responds battery saving is still soft and still works.
There are many types of governors. Some are for single-core processors and some designed for dual-core processors. In stock kernel, there are five governors and quasar kernel, there are a lot more.
1: OnDemand
2: OndemandX
3: Performance
4: Powersave
5: Conservative
6: Userspace
7: Min Max
8: Interactive
9: InteractiveX
10: Smartass
11: SmartassV2
12: Scary
13: Lagfree
14: Smoothass
15: Brazilianwax
16: SavagedZen
17: Lazy
18: Lionheart
19: LionheartX
20: Intellidemand
21: Hotplug
22: Wheatley
23: Lulzactive
24: AbyssPlug
25. BadAss
26. Ktoonservative
27. AssWax
28. Sleepy
29. Hyper
1: OnDemand Governor:
This governor has a hair trigger for boosting clockspeed to the maximum speed set by the user. If the CPU load placed by the user abates, the OnDemand governor will slowly step back down through the kernel's frequency steppings until it settles at the lowest possible frequency, or the user executes another task to demand a ramp.
OnDemand has excellent interface fluidity because of its high-frequency bias, but it can also have a relatively negative effect on battery life versus other governors. OnDemand is commonly chosen by smartphone manufacturers because it is well-tested, reliable, and virtually guarantees the smoothest possible performance for the phone. This is so because users are vastly more likely to ***** about performance than they are the few hours of extra battery life another governor could have granted them.
This final fact is important to know before you read about the Interactive governor: OnDemand scales its clockspeed in a work queue context. In other words, once the task that triggered the clockspeed ramp is finished, OnDemand will attempt to move the clockspeed back to minimum. If the user executes another task that triggers OnDemand's ramp, the clockspeed will bounce from minimum to maximum. This can happen especially frequently if the user is multi-tasking. This, too, has negative implications for battery life.
2: OndemandX:
Basically an ondemand with suspend/wake profiles. This governor is supposed to be a battery friendly ondemand. When screen is off, max frequency is capped at 500 mhz. Even though ondemand is the default governor in many kernel and is considered safe/stable, the support for ondemand/ondemandX depends on CPU capability to do fast frequency switching which are very low latency frequency transitions. I have read somewhere that the performance of ondemand/ondemandx were significantly varying for different i/o schedulers. This is not true for most of the other governors. I personally feel ondemand/ondemandx goes best with SIO I/O scheduler.
3: Performance Governor:
This locks the phone's CPU at maximum frequency. While this may sound like an ugly idea, there is growing evidence to suggest that running a phone at its maximum frequency at all times will allow a faster race-to-idle. Race-to-idle is the process by which a phone completes a given task, such as syncing email, and returns the CPU to the extremely efficient low-power state. This still requires extensive testing, and a kernel that properly implements a given CPU's C-states (low power states).
4: Powersave Governor:
The opposite of the Performance governor, the Powersave governor locks the CPU frequency at the lowest frequency set by the user.
5:Conservative Governor:
This biases the phone to prefer the lowest possible clockspeed as often as possible. In other words, a larger and more persistent load must be placed on the CPU before the conservative governor will be prompted to raise the CPU clockspeed. Depending on how the developer has implemented this governor, and the minimum clockspeed chosen by the user, the conservative governor can introduce choppy performance. On the other hand, it can be good for battery life.
The Conservative Governor is also frequently described as a "slow OnDemand," if that helps to give you a more complete picture of its functionality.
6: Userspace Governor:
This governor, exceptionally rare for the world of mobile devices, allows any program executed by the user to set the CPU's operating frequency. This governor is more common amongst servers or desktop PCs where an application (like a power profile app) needs privileges to set the CPU clockspeed.
7: Min Max
well this governor makes use of only min & maximum frequency based on workload... no intermediate frequencies are used.
8: Interactive Governor:
Much like the OnDemand governor, the Interactive governor dynamically scales CPU clockspeed in response to the workload placed on the CPU by the user. This is where the similarities end. Interactive is significantly more responsive than OnDemand, because it's faster at scaling to maximum frequency.
Unlike OnDemand, which you'll recall scales clockspeed in the context of a work queue, Interactive scales the clockspeed over the course of a timer set arbitrarily by the kernel developer. In other words, if an application demands a ramp to maximum clockspeed (by placing 100% load on the CPU), a user can execute another task before the governor starts reducing CPU frequency. This can eliminate the frequency bouncing discussed in the OnDemand section. Because of this timer, Interactive is also better prepared to utilize intermediate clockspeeds that fall between the minimum and maximum CPU frequencies. This is another pro-battery life benefit of Interactive.
However, because Interactive is permitted to spend more time at maximum frequency than OnDemand (for device performance reasons), the battery-saving benefits discussed above are effectively negated. Long story short, Interactive offers better performance than OnDemand (some say the best performance of any governor) and negligibly different battery life.
Interactive also makes the assumption that a user turning the screen on will shortly be followed by the user interacting with some application on their device. Because of this, screen on triggers a ramp to maximum clockspeed, followed by the timer behavior described above.
9: InteractiveX Governor:
Created by kernel developer "Imoseyon," the InteractiveX governor is based heavily on the Interactive governor, enhanced with tuned timer parameters to better balance battery vs. performance. The InteractiveX governor's defining feature, however, is that it locks the CPU frequency to the user's lowest defined speed when the screen is off.
10: Smartass
Is based on the concept of the interactive governor.
I have always agreed that in theory the way interactive works – by taking over the idle loop – is very attractive. I have never managed to tweak it so it would behave decently in real life. Smartass is a complete rewrite of the code plus more. I think its a success. Performance is on par with the “old” minmax and I think smartass is a bit more responsive. Battery life is hard to quantify precisely but it does spend much more time at the lower frequencies.
Smartass will also cap the max frequency when sleeping to 352Mhz (or if your min frequency is higher than 352 – why?! – it will cap it to your min frequency). Lets take for example the 528/176 kernel, it will sleep at 352/176. No need for sleep profiles any more!"
11: SmartassV2:
Version 2 of the original smartass governor from Erasmux. Another favorite for many a people. The governor aim for an "ideal frequency", and ramp up more aggressively towards this freq and less aggressive after. It uses different ideal frequencies for screen on and screen off, namely awake_ideal_freq and sleep_ideal_freq. This governor scales down CPU very fast (to hit sleep_ideal_freq soon) while screen is off and scales up rapidly to awake_ideal_freq (500 mhz for GS2 by default) when screen is on. There's no upper limit for frequency while screen is off (unlike Smartass). So the entire frequency range is available for the governor to use during screen-on and screen-off state. The motto of this governor is a balance between performance and battery.
12: Scary
A new governor wrote based on conservative with some smartass features, it scales accordingly to conservatives laws. So it will start from the bottom, take a load sample, if it's above the upthreshold, ramp up only one speed at a time, and ramp down one at a time. It will automatically cap the off screen speeds to 245Mhz, and if your min freq is higher than 245mhz, it will reset the min to 120mhz while screen is off and restore it upon screen awakening, and still scale accordingly to conservatives laws. So it spends most of its time at lower frequencies. The goal of this is to get the best battery life with decent performance. It will give the same performance as conservative right now, it will get tweaked over time.
13: Lagfree:
Lagfree is similar to ondemand. Main difference is it's optimization to become more battery friendly. Frequency is gracefully decreased and increased, unlike ondemand which jumps to 100% too often. Lagfree does not skip any frequency step while scaling up or down. Remember that if there's a requirement for sudden burst of power, lagfree can not satisfy that since it has to raise cpu through each higher frequency step from current. Some users report that video playback using lagfree stutters a little.
14: Smoothass:
The same as the Smartass “governor” But MUCH more aggressive & across the board this one has a better battery life that is about a third better than stock KERNEL
15: Brazilianwax:
Similar to smartassV2. More aggressive ramping, so more performance, less battery
16: SavagedZen:
Another smartassV2 based governor. Achieves good balance between performance & battery as compared to brazilianwax.
17: Lazy:
This governor from Ezekeel is basically an ondemand with an additional parameter min_time_state to specify the minimum time CPU stays on a frequency before scaling up/down. The Idea here is to eliminate any instabilities caused by fast frequency switching by ondemand. Lazy governor polls more often than ondemand, but changes frequency only after completing min_time_state on a step overriding sampling interval. Lazy also has a screenoff_maxfreq parameter which when enabled will cause the governor to always select the maximum frequency while the screen is off.
18: Lionheart:
Lionheart is a conservative-based governor which is based on samsung's update3 source.
The tunables (such as the thresholds and sampling rate) were changed so the governor behaves more like the performance one, at the cost of battery as the scaling is very aggressive.
19: LionheartX
LionheartX is based on Lionheart but has a few changes on the tunables and features a suspend profile based on Smartass governor.
20: Intellidemand:
Intellidemand aka Intelligent Ondemand from Faux is yet another governor that's based on ondemand. Unlike what some users believe, this governor is not the replacement for OC Daemon (Having different governors for sleep and awake). The original intellidemand behaves differently according to GPU usage. When GPU is really busy (gaming, maps, benchmarking, etc) intellidemand behaves like ondemand. When GPU is 'idling' (or moderately busy), intellidemand limits max frequency to a step depending on frequencies available in your device/kernel for saving battery. This is called browsing mode. We can see some 'traces' of interactive governor here. Frequency scale-up decision is made based on idling time of CPU. Lower idling time (<20%) causes CPU to scale-up from current frequency. Frequency scale-down happens at steps=5% of max frequency. (This parameter is tunable only in conservative, among the popular governors)
To sum up, this is an intelligent ondemand that enters browsing mode to limit max frequency when GPU is idling, and (exits browsing mode) behaves like ondemand when GPU is busy; to deliver performance for gaming and such. Intellidemand does not jump to highest frequency when screen is off.
21: Hotplug Governor:
The “hotplug” governor scales CPU frequency based on load, similar to “ondemand”. It scales up to the highest frequency when “up_threshold” is crossed and scales down one frequency at a time when “down_threshold” is crossed. Unlike those governors, target frequencies are determined by directly accessing the CPUfreq frequency table, instead of taking some percentage of maximum available frequency.
The key difference in the “hotplug” governor is that it will disable auxillary CPUs when the system is very idle, and enable them again once the system becomes busy. This is achieved by averaging load over multiple sampling periods; if CPUs were online or offlined based on a single sampling period then thrashing will occur.
Sysfs entries exist for “hotplug_in_sampling_periods” and for “hotplug_out_sampling_periods” which determine how many consecutive periods get averaged to determine if auxillery CPUs should be onlined or offlined. Defaults are 5 periods and 20 periods respectively. Otherwise the standard sysfs entries you might find for “ondemand” and “conservative” governors are there.
Obviously, this governor is only available on multi-core devices.
22: Wheatley
in short words this govenor is build on “ondemand” but increases the C4 state time of the CPU and doing so trying to save juice.
23: Basically interactive governor with added smartass bits and variable (as opposed to fixed amout) frequency scaling, based on currently occuring cpu loads. Has, like smartass, a sleep profile built-in. See link for details on exact scaling.
24: Abyssplug governor is a modified hotplug governor.
25. BadAss Governor:
Badass removes all of this "fast peaking" to the max frequency. On a typical system the cpu won't go above 918Mhz and therefore stay cool and will use less power. To trigger a frequency increase, the system must run a bit @ 918Mhz with high load, then the frequency is bumped to 1188Mhz. If that is still not enough the governor gives you full throttle. (this transition should not take longer than 1-2 seconds, depending on the load your system is experiencing)
Badass will also take the gpu load into consideration. If the gpu is moderately busy it will bypass the above check and clock the cpu with 1188Mhz. If the gpu is crushed under load, badass will lift the restrictions to the cpu.
26, Ktonnservative
Ondemand scales to the highest frequency as soon as a load occurs. Conservative scales upward based on the frequency step variable which means for the most part will scale through every frequency to achieve the target load thresholds. What this practically means is ondemand is prone to wasting power on unneeded clock cycles. Ondemand also features something called a down differential, this variable determines how long the governor will remain at the given frequency before scaling down. Conservative does not have this, but instead relies on having a down threshold which insures that as soon as the load drops below a given variable it scales down as fast as the sampling rate allows. The result to this is a governor which attempts to keep the load level tolerable and save you battery! Now ! Ktoonservative Is that but in addition contains a hotpluging variable which determines when the second core comes online. The governor shuts the core off when it returns to the second lowest frequency thus giving us a handle on the second performance factor in our CPUs behavior. While by default conservative is a poor performer it can be made to perform comparably to even performance governor. Here are some settings to discuss and start with. They are slightly less battery friendly under a load but very very well performing.
27. AssWax
So far, all I have found about this Governor is that it belongs in the interactive family. I'll update this when I find more
28. Sleepy
The Sleepy (formerly known as Solo) is an attempt to strike a balance between performance and battery power to create. It is based on the getweakten Ondemand of Arighi and is optimized for the SGS2. It may include imoseyon's Ondemandx with some tweaks Down_sampling and other features that set by the user through the sysfs of "echo" call. Sleepy is the behavior of Ondemandx when he is in action, very similar.
29. Hyper
The Hyper (formerly known as kenobi) is an aggressive smart and smooth, optimized for SGS2 getweakt and, based on the Ondemand, which was getweakt of Arighi and was equipped with several features of Ondemandx suspend imoseyon. (Added by sysfs, the settings suspend_freq and suspend Imoseyon's code) is the behavior of the hyper Ondemand if he is in action, very similar. He also has the Arighi's fast_start deep_sleep and detection features. In addition, the maximum frequency is in suspend mode 500Mhz.
Credits goes to:
http://icrontic.com/discussion/95140...m-tuner-tegrak
http://forum.xda-developers.com/show....php?t=1369817
What is a scheduler?
In a multitasking operating system, there must be an instance, the processes that want to run, CPU time and allocates it "goes to sleep" after the allotted time (timeslice) again. This instance is called the scheduler, such as opening and closing applications. that is, how fast they are open and how long they are kept in RAM.
I / O scheduler can have many purposes like:
To minimize time searching on the hard disk
Set priorities for specific process requests
To regulate a particular portion of the bandwidth of the data carrier to each running process
To guarantee certain process requests within a certain time
Which scheduler are available?
CFQ
Deadline
VR
Simple
Noop
Anticipatory
BFQ
Sio
Anticipatory:
Two important things here are indicative of that event:
- Looking on the flash drive is very slow from Equip
- Write operations while at any time are processed, however, be read operations preferred, ie, this scheduler returns the read operations a higher priority than the write operations.
Benefits:
- Requests of read accesses are never treated secondarily, that has equally good reading performance on flash drives like the noop
Disadvantages:
- Requests from process operations are not always available
- Reduced write performance on high-performance hard drives
CFQ:
The CFQ - Completely Fair Queuing - similar to the Dead Line maintains a scalable continuous Prozess-I/O-Warteschlange, ie the available I / O bandwidth tried fairly and evenly to all I / O requests to distribute. He created a statistics between blocks and processes. With these statistics it can "guess" when the next block is requested by what process, ie each process queue contains requests of synchronous processes, which in turn is dependent upon the priority of the original process. There is a V2 and the CFQ has some fixes, such as were the I / O request, hunger, and some small search backward integrated to improve the responsiveness.
Benefits:
- Has the goal of a balanced I / O performance to deliver
- The easiest way to set
- Excellent on multiprocessor systems
- Best performance of the database after the deadline
Disadvantages:
- Some reported user that the media scanning would take this very very long time and this by the very fair and even distribution of bandwidth on the I / O operations during the boot process is conditioned with the media scanning is not necessarily the highest should have priority
- Jitter (worst case delay) can sometimes be very high because the number of competing with each other process tasks
Deadline:
This scheduler has the goal of reducing I / O wait time of a process of inquiry. This is done using the block numbers of the data on the drive. This also blocks an outlying block numbers are processed, each request receives a maximum delivery time. This is in addition to the Governor BFQ very popular and in many well known kernels, such as the Nexus S Netarchy. He was indeed better than the BFQ, but compared to the VR he will be weaker.
Benefits:
- Is nearly a real-time scheduler.
- Characterized by reducing the waiting time of each process from - best scheduler for database access and queries.
- Bandwidth requirements of a process, eg what percentage does a CPU is easy to calculate.
- As the Governor-noop ideal for flash drives
Disadvantages:
- If the system is overloaded, can go a lost set of processes, and is not as easy to predict
SIO:
It aims to achieve with minimal effort at a low latency I / O requests. Not a priority to put in queue, instead simply merge the requests. This scheduler is a mix between the noop and deadline. With him there is no conversion or sorting of requests.
Benefits:
- It is simple and stable. - Minimized Starvations (starvation) for inquiries
Disadvantages:
- Slow random write speeds on flash drives as opposed to other schedulers. - Sequential read speeds on flash drives, not as good
Noop:
The noop scheduler is the simplest of them. He is best suited for storage devices that are not subject to mechanical movements, such as our flash drives in our SGSII's to use to access the data. The advantage is that flash drives do not require rearrangement of the I / O requests, unlike normal hard drives. ie the data that come first are written first. He's basically not a real scheduler, as it leaves the scheduling of the hardware.
Benefits:
- Adds all incoming I / O requests in a first-come-who-first-served queue and implements requests with the fewest number of CPU cycles, so also battery friendly
- Is suitable for flash drives because there is no search errors
- Good data throughput on db systems
Disadvantages:
- Reducing the number of CPU cycles corresponds to a simultaneous decline in performance einhergehendem
VR:
Unlike other scheduling software, synchronous and asynchronous requests are not handled separately, but it will impose a fair and balanced within this deadline requests, that the next request to be served is a function of distance from the last request. The VR is a very good scheduler with elements of the deadline scheduler. He will probably be the best for MTD Android devices. He is the one who can make the most of the benchmark points, but he is also an unstable schedulers, because his performance falter. Sometimes they fluctuate below the average, sometimes it fluctuates above the average, but if above, then he is the best.
Benefits:
- Is the best scheduler for benchmarks
Disadvantages:
- Performance variability can lead to different results
- Very often unstable or unzverlässig
Simple:
As the name suggests, it is more of a simple or simple scheduler. Especially suitable for EMMC devices. He is reliable, maybe not as good as the VR, when this time has a good day, but he is despite all this very performance-based and does his best. At the moment it is the default scheduler in quasar kernel.
Advantages: - not known
Cons: - not known
BFQ:
Instead requests divided into time segments as the CFQ has, on the BFQ budget. The flash drive will be granted an active process until it has exhausted its budget (number of sectors on the flash drive). The awards BFQ high budget does not read tasks.
Benefits:
- Has a very good USB data transfer rate.
- Be the best scheduler for playback of HD video recording and video streaming (due to less jitter than CFQ Scheduler, and others)
- Regarded as a very precise working Scheduler
- Delivers 30% more throughput than CFQ
Disadvantages:
- Not the best scheduler for benchmarks - higher budgets that were allocated to a process that can affect the interactivity and bring with it increased latency.
How can I change the governor and scheduler?
There are two ways to change the governor and schedulers, as well as the settings for the Governorn. Either manually, in which you use a file manager like Root Explorer and then knows how to / sys / devices / system and then change the files to his wishes, provided you what you're doing, or via a graphical interface or by phone as SetCPU Voltage Control. These are the most prominent apps when it comes to adjusting the governor and / or scheduler.
- SetCPU are, besides the possibility of the clock speed of the CPU, setting profiles in certain situations, only to change the way the governor. The scheduler can not change it.
- Voltage control can alter both the governor and the scheduler, but has no way to adjust behavior profiles. While you can set various overclocking, Governor and scheduler profiles manually, but nothing more. Nevertheless, I prefer the VC, since it is simple and gives me the opportunity to change the scheduler.
Credit goes to Tinzdroid

Good find. I found that a few months ago when i had a few governor questions.

That's a lot of governors. Too many honestly. How's it go? "Too much of a good thing is bad" I'd say 29 +1 (pegasusq isn't listed) is just overkill given that a few are just custom rehashes of others that can be done via apps or scripts but I do understand the point. Seems we're getting to a point where we'll need to narrow it down to the gems though. For multi-core phones that list is small unless you do some editing and/or scripts as only a few (hotplug and pegasusq mostly, abyssplug too I think) are naturally multi-core aware. The rest will only use core0.
Good find though. Normally you only find ones with about 1/2 of them listed.
Sent from my SPH-D710 using xda app-developers app

How about a governor named "fantasy"? Have this on my tablet set as default one by manufacturer.

Aessaya said:
How about a governor named "fantasy"? Have this on my tablet set as default one by manufacturer.
Click to expand...
Click to collapse
Did a simple google search, found the following info at http://tabletrepublic.com/forum/novo-7-elf/cpu-running-1008mhz-696.html
Antutu cpu works better for me. and so far, i set my cpu speed at 912 max 60 min, fantasy governor. Because this tablet has high resolution and require cpu power, it is better not to set the cpu max speed too low.
And
http://www.slatedroid.com/topic/30592-apps-for-cpu-speed-mod-recommendation/
'fantasy' - This driver adds a dynamic cpu freq policy governor.
The governor does a periodic polling and changes frequency based on the CPU utilization.
The support for this governor depends on CPU capability to do fast frequency switching (i.e, very low latency frequency transitions).

lulzactiveq is my personal choice, but you need to tweak the values.

Thank you for the post!

Thank you for the write up, I've seen all of them, but didn't know until now how the user created ones worked over presets. This should be stickied for every device, applies to every android device I have.

{KERNEL}[JB][TWRP+CWM]Trinity Ultimate Kernel V2.2 - FiXed - UltraKernelX - <OTA> -XT

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INTRODUCTION -
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Changelog -
V2.1A | 2.2B ( Re-Fixed and Re-Vamped Version )
Added CRT Hack
Kernel 3.4.20 Thanks To @Forzaferrarileo For Commit
Added New TCP Congestion Control Thanks To @Forzaferrarileo For Commit
Weak WiFi Tweak
Switched To Forza. OC Table Thanks To @Forzaferrarileo For Commit
Simple KGSL
Re-Enabled CONFIG_TRINITY_CHANGE ~ Easy 1.7 To 2.0 Ghz
eMMC in Sleep mode before suspend
Increased DMA size To 1 * 16
Enable AFTR Feature
Added Frandom
Added SLQB Memory Allocator
Revamped VMDirty
Revamped VM
Revamped PageWriteBack
Fix Benchmark Score Output
Initial 2 BootSplash - Waiting For @mericon Bootsplash
Enabled Group Scheduling
Reverted 30 Touch Gestures
Added Conservative Governor
Added CPU1 Fix V1.3 - Revamped
Added New Mpdecision - Revamped
Added Stable 2.0Ghz OC
Added Stable Voltage
Increased ReadAHead
Added CPU1 and CPU0 Info
Added Workaround To Link CPU0 and CPU1
Added Initial File for 1.7Ghz and 2.0Ghz - CONFIG_TRINITY_CHANGER=y For 2.0 and =N for 1.7
Revamped Fastcharge
Revamped I/O
Added -O3 Optimization
Increased I/O Float
Added NTFS Support Again
Removed Old Mpdecision Replaced with CPU1 Work
Frandom V1.1
Added Initial Files For ZRAM 1.1
Added Initial Files For Snappy Google Compression
Stat For CPU1 Mpdecision Should Update From Time To Time
V2.0 - Uploaded
Using Newest TWRP
Re-Enabled Color Control
FastCharge V1.3
Smooth Cpufreq Scrolling - From galaxy s2
Re-Enabled MSM_Thermal_Management 8x60 | 8960
GPU OC (?) - What is "(?)" In A Possibility That I Won't Be Added
Added SMARTMAX
Added BADASS
Added Wheatley
msm : rpm-smd : Configure WQ for High Priority
Added LIONHEART
Added Fiops
Added ROW
Added FiFo
Added Conservative
Added I/O Tweak V1.3
Added Ondemand Tweak
Possible Fix For cpu core #1
V1.9 - Uploaded
Using 1.5 Kernel Source
Using Linaro
New VR
New SIO
New CFQ
New Dancedance
Added Mpdecision V2.0
Battery Tweak
mpdecision
ZRAM
Force To Charge At Unsupported Chargers
Optimized Build Flags
msm: cpufreq: Configure WQ for higer priority
msm_fb: display: Use spinlock instead of mutex in vsync timer handler
lib/memcopy: use glibc version
switch do_fsync() to fget_light()
Lowered Swap
Tweaked Page Write Back
JIT For Default
Update Topology V1
Added XZ Compression
Boost I/O Performance
LOAD_FREQ (4*HZ+61) avoids loadavg More
random: add new get_random_bytes_arch() function
block/deadline: tweaked for better performance on android
Reduced Android Logger RAM usage
mm.c Tweak
Drivers Tweak
I/O Tweak
msm: cpufreq: Add API to allow limiting of min and max cpu frequencies
Increased Battery Capacity
V1.8 - Uploaded
OC Upto 2.0Ghz
Patched Freq to 1.5Ghz
Fixed All Freq Except Cpu1
Revamped All Governor Except Ondemand
V1.7 - Uploaded
Added Source Added AOSP Source Defconfig
Increased 2D and 3D
Compiled With code sourcery
Fastcharge V2
remove 64Bit
I/O Tweak
Tweaked Lionheart
Tweaked Ondemand
Tweaked Dancedance
Tweaked Mpdecision
Tweaked UV
Added Battery tweak V2 Alpha
V1.6 - Uploaded
BB Installer Thanks to @letama
Exp Version
TWRP
Added @mericon to my Team.
Added New Bootsplash
Added New 3D OC
AROMA Installer
Kernel 3.4.49 with SoD Fix, Memory Leak Fix, And FPS Drop Fix - WIP -
2D OC Scallable - Upto 310Mhz
Fixed Missing Config Of Governors
Improve ADB file push/pull performance
msm: iommu: Synchronize access to IOMMU cfg port
msm: kgsl: Synchronize access to IOMMU cfg port
msm: kgsl: Make the GPU device aware of the next pending event
Improve MTP File Transfer Performance
V1.5 - Uploaded
Added Fiops
Added Smoothass
Added Lagfree
Added BrazillianWax
SuperStamina Support Beta #1 @ 1.7
driver/thermal: create kernel MSM thermal management for MSM8x60
mpdecision
msm: cpufreq: Configure WQ for higer priority
msm_fb: display: Use spinlock instead of mutex in vsync timer handler
lib/memcopy: use glibc version
switch do_fsync() to fget_light()
LOAD_FREQ (4*HZ+61) avoids loadavg More
random: add new get_random_bytes_arch() function
block/deadline: tweaked for better performance on android
Reduced Android Logger RAM usage
msm: cpufreq: Add API to allow limiting of min and max cpu frequencies
Increased Battery Capacity
Increased Charging Current - Higher is Better FTW!
V1.4- Uploaded
REMOVED DOOMLORD NEW RAMDISK VIOLATES I READ OP ALREADY. Thanks Re-Uploading
Reverted To the OLD Freq. Table
Remove Frequency Table Based On Fer. Kernel
Removed Native GPU OC That I Made
LINARO Compiled
ZRAM
Force To Charge At Unsupported Chargers
Optimized Build Flags
Added Lagfree - Not In Kernel In Defconfig It Will Be Available @ 1.5
Added BrazilianWax - Not In Kernel In Defconfig It Will Be Available @ 1.5
Remove Wheatly
Added Smoothass - Not In Kernel In Defconfig It Will Be Available @ 1.5
Fix Leak Memory
Fix Frequency Boot-up
V1.3 - Skipped Private Testing For 24hrs
V1.2 - Uploaded!
Voltage Control
New Build Flag
I/O Tweak V2
New Bootsplash By @Yakandu
GPU OC 2D/3D
GPU Control
New Frequency Table
Battery Tweak
FastCharge V1 Port from NOVA
V1.1 - Uploaded!
Increased I/O Performance x2
SIO Tweak
Compiled with Linaro Cortex
Linaro Optimization
Added Wheatly
Added SIO
Added HotPlug
Increased Entropy
Lowered Swap
Tweaked Page Write Back
JIT For Default
Update Topology V1
Added XZ Compression
Boost I/O Performance
V1.0
DoomLord RAMDISK
Pre-Rooted
Busybox
Compiled With Linaro ToolChain
Snapdragon Optimization
mm.c Tweak
Drivers Tweak
I/O Tweak
VM_READHEAD Tweak Increased
Battery Charge Tweak
dancedance Governor
Overclocking Support
Undervolting Support
Future Plan -
TWRP Recovery
Add Fugeswap
Arm: Allow CPU-supported unaligned accesses
CS ToolChain
O3 Optimization
SuperStamina Support
All Governors
USB OTG Support
USB Fast Charge
Nightmare Governor - TEST
Trinity Governor Based On - Dancedance
Tweak audio buffers for Beats
Complete I/O Scheduler
Many More That Is My Plan For 1.2 To 1.5
What Is A Kernel?
Android (like many other Smartphone operating systems) runs on the Linux kernel. The Linux kernel was created in the early 1990’s by a gentleman named Linus Torvalds in Helsinki Finland. It’s incredibly stable, incredibly friendly, and incredibly difficult for the layman to understand and modify. Thankfully it’s also very popular so it has been ported on to a multitude of hardware, including our Android devices.
Think of the kernel as an interface layer between the hardware and software on your device. The kernel decides when things happen, such as the LED indicator gets lit. An application sends a request to the operating system to blink the LED. The operating system then sends the request to the kernel, which makes the light flash for the amount of time requested by the OS.
What sounds like a round-about way to get things done is also what makes the system so scalable and robust. Application developers only have to code in a way the operating system understands and the kernel makes it work on the hardware. This also keeps the application running in it’s own user-space and separate from the kernel. That means when you run the latest uber-cool app that wasn’t designed for your particular OS version, or is still very beta and it crashes, the kernel gives you the option to Force Close the application and the kernel can run untouched.
In a standard Android ROM (we will leave developer images and the like for another discussion) the kernel is bundled along with a set of instructions that tell the device how to load the kernel and the OS during boot. This is the boot.img that you see inside a zipped ROM that you're not able to easily open. The device knows to extract this image to internal memory (the ramdisk) and follow a series of scripts (init scripts) to load the kernel and then the other portions of the OS. That’s what’s happening while you’re watching the boot animation. Interestingly enough this is done the same way for a PC, your smartphone, an Android tablet, or even a smart Linux powered toaster. If you’re feeling exceptionally geeky, plug your Android phone into the USB port on your PC and let the PC boot from the USB device. No, it doesn’t actually load, but you can watch the animation while it tries to match up the hardware support with what’s inside your PC. As I said, Linux is amazingly scalable and as a result so is Android.
​ Credits -
DooMLord
Sony
XDA
BitBucket
!THREAD UNDER CONSTRUCTION!​

Mpdecision and Sweep2Wake @ 1.5 Kernel SooN!
What is msm_mpdecision?​
100% kernel based multi core decision! (should cpu1 be online or not?)
This replaces your /system/bin/mpdecision binary which is renamed by the installer to mpdecision_backup.
Check /sys/kernel/msm_mpdecision/conf/ for the configuration.
startdelay = time until mpdecision starts doing it's magic (70000)
delay = time between checks (500)
pause = if something else plugs in the cpu, fall asleep for 10000
scroff_single_core = if the screen is off, don't plug in cpu1 (1)
nwns_threshold_up = runqueue threshold, if this is reached cpu1 will be hotplugged (35)
nwns_threshold_down = runqueue threshold, if this is reached cpu1 will be unplugged (5)
twts_threshold_up = time threshold, this amount of time must have passed (250)
twts_threshold_down = same as above (250)
enabled = enable(1) or disable(0) mpdecision. This does not affect scroff_single_core!
idle_freq = a value against that will be checked if a core +/- is requested. (486000)
If cpu0 is below that value and a core up of cpu1 is requested, nothing will happen.
If cpu1 is above that value and a core down of cpu1 is requested, nothing will happen. (otherwise it would now put down cpu1 even though it is still working)
Click to expand...
Click to collapse
GOVERNORS
----
Official Governors to Be Added In My Kernel
----
I) MANUAL:
These are the 19 governors we're talking about.
1) Ondemand
2) Ondemandx
3) Conservative
4) Interactive
5) Interactivex
6) Lulzactive
7) Lulzactiveq
8) Smartass
9) SmartassV2
10) Intellidemand
11) Lazy
12) Lagfree
13) Lionheart
14) LionheartX
15) Brazilianwax
16) SavagedZen
17) Userspacce
18) Powersave
19) Performance
NOTE: Info on Samsung's own multi-core aware governor - Pegasusq is here
1) Ondemand:
Default governor in almost all stock kernels. One main goal of the ondemand governor is to switch to max frequency as soon as there is a CPU activity detected to ensure the responsiveness of the system. (You can change this behavior using smooth scaling parameters, refer Siyah tweaks at the end of 3rd post.) Effectively, it uses the CPU busy time as the answer to "how critical is performance right now" question. So Ondemand jumps to maximum frequency when CPU is busy and decreases the frequency gradually when CPU is less loaded/apporaching idle. Even though many of us consider this a reliable governor, it falls short on battery saving and performance on default settings. One potential reason for ondemand governor being not very power efficient is that the governor decide the next target frequency by instant requirement during sampling interval. The instant requirement can response quickly to workload change, but it does not usually reflect workload real CPU usage requirement in a small longer time and it possibly causes frequently change between highest and lowest frequency.
2) Ondemandx:
Basically an ondemand with suspend/wake profiles. This governor is supposed to be a battery friendly ondemand. When screen is off, max frequency is capped at 500 mhz. Even though ondemand is the default governor in many kernel and is considered safe/stable, the support for ondemand/ondemandX depends on CPU capability to do fast frequency switching which are very low latency frequency transitions. I have read somewhere that the performance of ondemand/ondemandx were significantly varying for different i/o schedulers. This is not true for most of the other governors. I personally feel ondemand/ondemandx goes best with SIO I/O scheduler.
3) Conservative:
A slower Ondemand which scales up slowly to save battery. The conservative governor is based on the ondemand governor. It functions like the Ondemand governor by dynamically adjusting frequencies based on processor utilization. However, the conservative governor increases and decreases CPU speed more gradually. Simply put, this governor increases the frequency step by step on CPU load and jumps to lowest frequency on CPU idle. Conservative governor aims to dynamically adjust the CPU frequency to current utilization, without jumping to max frequency. The sampling_down_factor value acts as a negative multiplier of sampling_rate to reduce the frequency that the scheduler samples the CPU utilization. For example, if sampling_rate equal to 20,000 and sampling_down_factor is 2, the governor samples the CPU utilization every 40,000 microseconds.
4) Interactive:
Can be considered a faster ondemand. So more snappier, less battery. Interactive is designed for latency-sensitive, interactive workloads. Instead of sampling at every interval like ondemand, it determines how to scale up when CPU comes out of idle. The governor has the following advantages: 1) More consistent ramping, because existing governors do their CPU load sampling in a workqueue context, but interactive governor does this in a timer context, which gives more consistent CPU load sampling. 2) Higher priority for CPU frequency increase, thus giving the remaining tasks the CPU performance benefit, unlike existing governors which schedule ramp-up work to occur after your performance starved tasks have completed. Interactive It's an intelligent Ondemand because of stability optimizations. Why??
Sampling the CPU load every X ms (like Ondemand) can lead to under-powering the CPU for X ms, leading to dropped frames, stuttering UI, etc. Instead of sampling the CPU at a specified rate, the interactive governor will check whether to scale the CPU frequency up soon after coming out of idle. When the CPU comes out of idle, a timer is configured to fire within 1-2 ticks. If the CPU is very busy between exiting idle and when the timer fires, then we assume the CPU is underpowered and ramp to max frequency.
5) Interactivex:
This is an Interactive governor with a wake profile. More battery friendly than interactive.
6) Lulzactive:
This new find from Tegrak is based on Interactive & Smartass governors and is one of the favorites.
Old Version: When workload is greater than or equal to 60%, the governor scales up CPU to next higher step. When workload is less than 60%, governor scales down CPU to next lower step. When screen is off, frequency is locked to global scaling minimum frequency.
New Version: Three more user configurable parameters: inc_cpu_load, pump_up_step, pump_down_step. Unlike older version, this one gives more control for the user. We can set the threshold at which governor decides to scale up/down. We can also set number of frequency steps to be skipped while polling up and down.
When workload greater than or equal to inc_cpu_load, governor scales CPU pump_up_step steps up. When workload is less than inc_cpu_load, governor scales CPU down pump_down_step steps down.
Example:
Consider
inc_cpu_load=70
pump_up_step=2
pump_down_step=1
If current frequency=200, Every up_sampling_time Us if cpu load >= 70%, cpu is scaled up 2 steps - to 800.
If current frequency =1200, Every down_sampling_time Us if cpu load < 70%, cpu is scaled down 1 step - to 1000.
7) Lulzactiveq:
Lulzactiveq is a modified lulzactive governor authored by XDA member robertobsc and is adapted in Siyah kernel for GS2 and GS3. Lulzactiveq aims to optimize the second version of luzactive from Tegrak by a) providing an extra parameter (dec_cpu_load) to make scaling down more sensible, and b) incorporating hotplug logic to the governor. Luzactiveq is the first ever interactive based governor with hotplugging logic inbuilt (atleast the first of its kind for the exynos platform). When CPU comes out of idle loop and it's time to make a scaling decision, if load >= inc_cpu_load CPU is scaled up (like original luzactiveq) and if load <dec_cpu_load, CPU is scaled down. This possibly eliminates the strict single cut-off frequency for luzactiveq to make CPU scaling decisions. Also, stand hotplug logic runs as a separate thread with the governor so that external hotplugging logic is not required to control hotplug in and out (turn On and Off) CPU cores in multi core devices like GS2 or GS3. Only a multi core aware governor makes real sense on muti-core devices. Lulzactiveq and pegasusq aims to do that.
8) Smartass:
Result of Erasmux rewriting the complete code of interactive governor. Main goal is to optimize battery life without comprising performance. Still, not as battery friendly as smartassV2 since screen-on minimum frequency is greater than frequencies used during screen-off. Smartass would jump up to highest frequency too often as well.
9) SmartassV2:
Version 2 of the original smartass governor from Erasmux. Another favorite for many a people. The governor aim for an "ideal frequency", and ramp up more aggressively towards this freq and less aggressive after. It uses different ideal frequencies for screen on and screen off, namely awake_ideal_freq and sleep_ideal_freq. This governor scales down CPU very fast (to hit sleep_ideal_freq soon) while screen is off and scales up rapidly to awake_ideal_freq (500 mhz for GS2 by default) when screen is on. There's no upper limit for frequency while screen is off (unlike Smartass). So the entire frequency range is available for the governor to use during screen-on and screen-off state. The motto of this governor is a balance between performance and battery.
10) Intellidemand:
Intellidemand aka Intelligent Ondemand from Faux is yet another governor that's based on ondemand. Unlike what some users believe, this governor is not the replacement for OC Daemon (Having different governors for sleep and awake). The original intellidemand behaves differently according to GPU usage. When GPU is really busy (gaming, maps, benchmarking, etc) intellidemand behaves like ondemand. When GPU is 'idling' (or moderately busy), intellidemand limits max frequency to a step depending on frequencies available in your device/kernel for saving battery. This is called browsing mode. We can see some 'traces' of interactive governor here. Frequency scale-up decision is made based on idling time of CPU. Lower idling time (<20%) causes CPU to scale-up from current frequency. Frequency scale-down happens at steps=5% of max frequency. (This parameter is tunable only in conservative, among the popular governors )
To sum up, this is an intelligent ondemand that enters browsing mode to limit max frequency when GPU is idling, and (exits browsing mode) behaves like ondemand when GPU is busy; to deliver performance for gaming and such. Intellidemand does not jump to highest frequency when screen is off.
11) Lazy:
This governor from Ezekeel is basically an ondemand with an additional parameter min_time_state to specify the minimum time CPU stays on a frequency before scaling up/down. The Idea here is to eliminate any instabilities caused by fast frequency switching by ondemand. Lazy governor polls more often than ondemand, but changes frequency only after completing min_time_state on a step overriding sampling interval. Lazy also has a screenoff_maxfreq parameter which when enabled will cause the governor to always select the maximum frequency while the screen is off.
12) Lagfree:
Lagfree is similar to ondemand. Main difference is it's optimization to become more battery friendly. Frequency is gracefully decreased and increased, unlike ondemand which jumps to 100% too often. Lagfree does not skip any frequency step while scaling up or down. Remember that if there's a requirement for sudden burst of power, lagfree can not satisfy that since it has to raise cpu through each higher frequency step from current. Some users report that video playback using lagfree stutters a little.
13) Lionheart:
Lionheart is a conservative-based governor which is based on samsung's update3 source. Tweaks comes from 1) Knzo 2) Morfic. The original idea comes from Netarchy. See here. The tunables (such as the thresholds and sampling rate) were changed so the governor behaves more like the performance one, at the cost of battery as the scaling is very aggressive.
To 'experience' Lionheart using conservative, try these tweaks:
sampling_rate:10000 or 20000 or 50000, whichever you feel is safer. (transition latency of the CPU is something below 10ms/10,000uS hence using 10,000 might not be safe).
up_threshold:60
down_threshold:30
freq_step:5
Lionheart goes well with deadline i/o scheduler. When it comes to smoothness (not considering battery drain), a tuned conservative delivers more as compared to a tuned ondemand.
14) LionheartX
LionheartX is based on Lionheart but has a few changes on the tunables and features a suspend profile based on Smartass governor.
15) Brazilianwax:
Similar to smartassV2. More aggressive ramping, so more performance, less battery.
16) SavagedZen:
Another smartassV2 based governor. Achieves good balance between performance & battery as compared to brazilianwax.
17) Userspace:
Instead of automatically determining frequencies, lets user set frequencies.
18) Powersave:
Locks max frequency to min frequency. Can not be used as a screen-on or even screen-off (if scaling min frequency is too low).
19) Performance:
Sets min frequency as max frequency. Use this while benchmarking!
So, Governors can be categorized into 3/4 on a high level:
1.a) Ondemand Based:
Works on "ramp-up on high load" principle. CPU busy-time is taken into consideration for scaling decisions. Members: Ondemand, OndemandX, Intellidemand, Lazy, Lagfree.
1.b) Conservative Based:
Members: Conservative, Lionheart, LionheartX
2) Interactive Based:
Works on "make scaling decision when CPU comes out of idle-loop" principle. Members: Interactive, InteractiveX, Lulzactive, Luzactiveq, Smartass, SmartassV2, Brazilianwax, SavagedZen.
3) Weird Category:
Members: Userspace, Powersave, Performance.
Thank To Droiphile

Which are the linaro beneficts? I heard a lot about it months ago...

megamarini said:
Which are the linaro beneficts? I heard a lot about it months ago...
Click to expand...
Click to collapse
Here you Go Buddy http://forum.xda-developers.com/showthread.php?t=1371044

TrinityHaxxorX said:
Here you Go Buddy http://forum.xda-developers.com/showthread.php?t=1371044
Click to expand...
Click to collapse
Thank you mate... and what about dance dance governor??? something really new??? i'm not able to find it on Google,...

we win a great devolper here ,, great job man you making alot of things in short time
keep up the good work

megamarini said:
Thank you mate... and what about dance dance governor??? something really new??? i'm not able to find it on Google,...
Click to expand...
Click to collapse
Yeah Its New...

TrinityHaxxorX said:
Yeah Its New...
Click to expand...
Click to collapse
It's battery friendly or performance?

sparxx4 said:
we win a great devolper here ,, great job man you making alot of things in short time
keep up the good work
Click to expand...
Click to collapse
Not A Shorttime lol I Worked 8-14Hrs For my ROM / Kernel Since Im Out of gaming Like MW3 and LOL So I Focus Development

megamarini said:
It's battery friendly or performance?
Click to expand...
Click to collapse
For my Opinion Yes... I'll Add the dancedance Info Later Im Still In my Friend house

@megamarini Thats Why Ive Default that as My Governor Its Likely Deepsleep Much better and the Performance is in the Core kernel or source files
It's Snuzzo's own creation. It's based on conservative, but with higher ramp rates (similar to lionheart) and better sleep routines (similar to wheatley).

TrinityHaxxorX said:
@megamarini Thats Why Ive Default that as My Governor Its Likely Deepsleep Much better and the Performance is in the Core kernel or source files
It's Snuzzo's own creation. It's based on conservative, but with higher ramp rates (similar to lionheart) and better sleep routines (similar to wheatley).
Click to expand...
Click to collapse
It looks very interesting... Thank you for your work!!:victory:

megamarini said:
It looks very interesting... Thank you for your work!!:victory:
Click to expand...
Click to collapse
Its Okay Just Give Feedback Later or Sooner

Oh yeah new kernel! XD
btw was the kernel boot up screen are SONY logo or?

jimRnor said:
Oh yeah new kernel! XD
btw was the kernel boot up screen are SONY logo or?
Click to expand...
Click to collapse
Cause I Dont have any Custom Bootsplash yet lol

yes its sony logo
___
almost 22 min on battery didnt lost 1% coooool

sparxx4 said:
yes its sony logo
___
almost 22 min on battery didnt lost 1% coooool
Click to expand...
Click to collapse
What Governor

ondemand
just flashed the kernel and didnt touch any thing
26 min on battery for 1% its roock dude with brightness almost 50% you can get more great job

sparxx4 said:
ondemand
just flashed the kernel and didnt touch any thing
26 min on battery for 1% its roock dude with brightness almost 50% you can get more great job
Click to expand...
Click to collapse
Good Use dancedance soon and give feedback

Future Plan -
TWRP Recovery
Add Fugeswap
Arm: Allow CPU-supported unaligned accesses
CS ToolChain
O3 Optimization
SuperStamina Support
All Governors
USB OTG Support
USB Fast Charge
Nightmare Governor - TEST
Trinity Governor Based On - Dancedance
Tweak audio buffers for Beats
Complete I/O Scheduler
Many More That Is My Plan For 1.2 To 1.5

[REF] [GUIDE][How to][TUTORIAL] - KT747 - KTweaker New User Guide & Settings

INTRODUCTION -
This guide is intended to help those who are coming to the Kernel KT747 by @ktoonsez. This thread and the subsequent Posts are intended to be as a Guide for users that are new to this Kernel and its Tweaker. Complete credit for the development of the Kernel goes to @ktoonsez. You can find his Kernel thread bellow.
KT747 - SGH-T999 Touchwiz & AOSP - Thread by Ktoonsez
Older Builds of the Kernel - Thread by @LuigiBull23
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"lightbox_close": "Close",
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​INTRODUCTION -
There are quiet a few times when users have asked for the choice, usage as well as definition of various parameters of the Governers and Schedulers. Hence I decided to write this guide as a way to help the users understand the various basic terms and parameters. I am perfectly aware that there are quiet a few excellent guides on the different ICS & JB Governers. As a matter of fact, I have linked to some of them. So eventhough I have given basic information on Governers in this kernel, it is not my primary purpose to serve this as the ultimate guide on that subject.
This is a living guide and given vastness of the subject, I will continue to modify the OP as well as subsequent posts.
Disclaimer:
I am not responsible if you end up with expensive brick. Read the guide as much as you want and ask questions before proceeding with overclocking.
Overclocking and undervolting is highly debatable, some say its good and some say its bad... so its upto you to proceed further. While on the word of Caution – I have personally managed to Smoke (I mean literally physically cause smoke) from a Tablet by testing SetCPU Overclocking on it.
Here’s another nice detail on why Friends don't let Friends do extreme Overclock or Undervolt! post by @dorimanx, the developer of the other excellent kernel.
PURPOSE / INTENT -
The intent of this thread is to help new users learn, and act as reference for more knowledgeable users, on the Governers & Schedulers incorporated into this Kernel. Another Purpose is to help those who are new to Overclocking & undervolting in general.
There are quite a few good guides on this forum regarding Overclocking. So Rather than writing one myself, I am going to refer to one by @bala_gamer, who has written a pretty comprehensive guide for the International version of Galaxy SIII. Even though the hardware is different between that phone and this one, the guide is good enough for those who are starting down this path and want to get basic understanding.
Another intentional purpose of this thread is to provide a platform to discuss Overclocking and undervolting settings for SGH-T999 specific version. Given that I wish offer to the experts a platform to discuss, in interest of New users and their phone, I have been careful enough to include warnings and footnotes where possible.
WHAT DO I GET BY OVERCLOCKING/UNDERVOLTING -
In short, modern Microprocessors, to a certain degree have a range of Operational frequency steps. Also especially for multiprocessor devices, it is possible to control when a processor comes into play and when it does not. Now, the main question that comes to mind is, why would you want to turn off processors? Well, consider this. It’s Kind of an analogy like a car engine. On a 6 Cylinder engine, the fuel consumption is a lot more. But if you were to turn off 2 out of the 6 cylinders, then there is still power to drive and fuel consumption is lower. Similarly, with one of the processor turned off, battery drain is reduced not to mention heat generation.
For a given processor, by design the higher the frequency it operates, the more raw power you have available to run applications. Typically on some of the previous generation single processor phones, its not possible to run Angry Birds or other games unless you run the processor consistently at its maximum operating frequency. So users may choose to Overclock the phone in order to run such Apps.
On the flip side, if you are a light user, then it will benefit if you turned off the other processor(s). This saves the battery. Given there are multitudes of Frequency steps, if the processor operates at lower frequency, there is less heat generated and less battery used. Before I proceed further, I am respectfully Quoting Castle_Bravo from here. He has summarized perfectly what I’d have said otherwise.
castle_bravo said:
In the pc world we have things like clock speeds, latency, read speed, bus speeds and things of this nature. Right now im going to talk about over clocking a processor, whether it's a gpu I or a cpu. When we over clock these devices, meaning make them go faster than originally rated by the manufacturer using software of any kind, these devices will also work harder. The faster the clock speed the hotter the component gets and the shorter it's life span is due to thermal stresses. Hence our manufacturer rating of speeds.
There are two ways to combat heat; heat is the main enemy in any high powered system (do a YouTube search of running a cpu with no heart sink). Add more cooling via more hardware and lower voltages applied to the component. Adding more cooling hardware is the preferred method. This is the best way because now that the component is working faster at the same temperatures it was at before on stock clock speeds it is, in terms of math, working LESS. This applies to ram, video card, cpu's and the like.
Typically, as you raise clock speeds you also have to RAISE voltages in order to keep it stable. There are exceptions like in a VERY minor over clock you can actually lower voltages. The trade off here is that with the larger cooling equipment and the faster clock speeds the processor will spend less time at peak load and return to idle faster. If set up correctly you can actually draw less cumulative power using higher voltages. This is assuming temperatures are the same for both scenarios of stock clock and over clock. BUT, more power applied equals more heat. Now, as we raise clock speeds and raise our voltage, we try to be on the edge of not enough. Because what does more power mean? More heat. And what does more heat mean? Less component life. Not only that but the components have a "healthy" voltage band due to tolerances in its manufacture so we don't want to exceed that.
We undervolt mainly to protect the equipment. Secondary is battery savings. We do not have the option of installing more hardware to cool our devices so all we can do is lower voltages. Lowering voltages will help keep the component cool because it is pulling less electrons. More power = more heat. the cpu will become unstable and make it work harder, which is counter productive and will have a reverse effect. So take that voltage too far down and now the component doesn't have enough power to perform its job properly or efficiently, making it work HARDER. What happens when a component works harder? It heats up. So we can actually have a reverse effect from our intended power savings.
Click to expand...
Click to collapse
Last But Not Least, here’s a nice Q&A by XDA User @droidphile for further reading. Although it is written for the Galaxy S2, quite a few parts do apply as this device too has dual core. Since that’s another SoC, apply the settings with caution if you at all wish to apply from that post.

Implementation of Overclocking & Undervolting by using KTweaker -
Given that Ktoonsez has an excellent app for this kernel; my intention is to provide a way for you to make the best usage of the same.
​ By default, when the kernel is freshly installed and you open the app for the first time, there should not be any error messages of any kind. The App settings are not permanent. So every time you re-boot the phone, you are restored to original Defaults. This is a great way to test out various settings to see if they work out or turn the phone into slowpoke.
As you can see in the screen shot, there are 7 major options.
GENERAL – This is the main setting area. This is where you control the phone’s operation and other settings around how it behaves. We will go into great details later on.
VOLTAGES – This allows you to control the CPU operating voltage at a given Frequency step. It plays a significant role when you are undervolting or Overclocking.
EXTRAS – Unlike the name, this section contains quite a few important settings that modify the phone’s behavior. Specifically how the phone reacts when the screen is turned off or when you are Navigating or charging the phone.
SET OPTIONS ON BOOT – As the name suggests, you get to choose if the settings you have changed are applied after you restart or not. Also if you choose to, you can also specify a time duration after Restart before your settings get applied.
BACKUP PREFS TO SDCARD – This simply allows you to make a backup of your settings to the internal SD Card. The path is /SDCARD/KTWEAKER/. You can also name the settings optionally.
RESTORE PREFS FROM SDCARD – As the name suggests, you can re-load your backed up settings. Comes in handy if you have one set of settings that really work and you want to experiment further.
LOAD DEFAULTS – This option simply sets all the settings to the value KTOONSEZ has set up in the kernel as initial values.

GENERAL SECTION -
​ This is perhaps the main section of the Kernel Controls. In this section you can choose wide variety of options that directly determine the performance of the phone as well as Battery life as a result.
There are several sub-menus as follows. As you can see in the screen-shot, there is a small comment on what the section does.
1. ENABLE OC STEPS
2. LOCK FREQUENCIES – There’s a little sub-section to choose minimum and maximum operating frequencies.
3. I/O SCHEDULERS
4. I/O SCHEDULER ADJUSTMENTS
5. CPU GOVERNORS
6. CPU GOVERNOR ADJUSTMENTS
7. AUTO HOTPLUG
1. ENABLE OC STEPS -
This is a simple Check box to enable Overclocking. Select this only if you are going to overclock. By doing so, you get higher range of frequencies to choose for the Minimum and Maximum frequencies. Do note, just because it lets you specify higher frequencies, does not mean you can set to the highest value. Permanently operating at Overclocked frequency may cause physical damage to your phone. Remember Qualcomm has set 1500 MHZ as the normal operating frequency for this CPU.
2. LOCK FREQUENCIES -
This is again a Check box that effectively pegs the operating frequencies to within the Range as specified by the Minimum Frequency and Maximum Frequency sliders.
The two sliders that are part of this section need to be set after very careful consideration. If you set the minimum frequency too low, then you run the risk of a sluggish and unresponsive phone when there are no apps running. For the maximum frequency, remember higher the frequency, more heat will be produced. Also the battery will drain faster. So give it some thought before setting the limits. Choose the values based on whether you are looking to save battery or get high performance and responsiveness.
Note – A side note on this, the CPU is actually located in the back, bellow the battery compartment. So you will notice the heat in that section. If you happen to have a bumper case on the phone, you won't notice actual temperature unless the phone is really hot.
7. AUTO HOTPLUG
This is a simple Checkbox that enables Hot-Plugging support. Hotpluging is a concept borrowed from Server Linux and is applicable to Android in the same manner. In short, it allows for CPUs being removed from Service or added to service on the fly, without needing OS level Restart. Effectively this, gives the kernel a choice to Take CPU Cores offline or bring them online. Some of the Governors we discussed above already support hotplugging. This checkbox ensures support for the remaining Governors.

3. I/O SCHEDULER –
Scheduler Guide Link
This menu offers a choice of all the android Schedulers available in this kernel.​
Given that there are so many excellent guides on the individual Schedulers, I do not wish to provide the same information again. (Besides this is indeed a vast topic by itself.) So without going to specific details, I am going to summarize what it means from a layman's point of view. For those with more technical inclination, I have provided a link to read further on each scheduler.
Think of an I/O Scheduler like an executive assistant to the Disc or storage of the phone. Just like the assistants, it effectively manages the disc reads or writing to it for all the processes. In particular, it determines what process gets prioritized and/or bandwidth. You have to understand; that each app you run has its own process as well as child processes it triggers. In addition, the OS too has its own processes that monitor various aspects of the phone. Effectively these are all the processes competing for the reading or writing. Based on that knowledge, you can choose whatever works best for your usage pattern. Later on I will be providing some sample settings to get you started.
Noop:
The noop scheduler is the simplest of them. It is best suited for Cell phone storage since it is flash media. As the flash drives do not require rearrangement of the I/O requests, the data that come first is written first (First in First Out). It's basically not a real scheduler, as it leaves out the scheduling of the hardware.
Benefits:
- Adds all incoming I / O requests in a first-come-who-first-served queue and implements requests with the fewest number of CPU cycles, so also battery friendly
- Is suitable for flash drives because there is no search errors
- Good data throughput on db systems
- Is nearly a real-time scheduler.
- Characterized by reducing the waiting time of each process from - best scheduler for database access and queries.
- Bandwidth requirements of a process, eg what percentage CPU is used is easy to calculate.
Disadvantages:
- If the system is overloaded, it may lose a set of processes, and is not as easy to predict
- Reducing the number of CPU cycles corresponds to a simultaneous decline in performance.
Deadline:
This scheduler has the goal of reducing I/O wait time of a process. This is done using the block numbers of the data on the drive. This also controls how outlying block numbers are processed, each request receives a maximum delivery time. This is in very popular like BFQ and Deadline:
Benefits:
- Is nearly a real-time scheduler.
- Characterized by reducing the waiting time of each process from - best scheduler for database access and queries.
- Bandwidth requirements of a process, eg what percentage does a CPU is easy to calculate.
- noop is ideal for flash drives
Disadvantages:
- If the system is overloaded, can go a lost set of processes, and is not as easy to predict. It is indeed better than the BFQ, but VR is even better.
ROW:
Reference - http://lwn.net/Articles/509829/
Read Over Write Scheduler. This scheduler ignores or backpedals the disc write operations, giving higher priority to the Read Operations.
Mobile devices prefer user experience; hence, the READ IO requests get as much priority as possible. The main idea is, if there are READ requests in pipe - dispatch them but don't delay the WRITE requests too much.
All the incoming requests are kept in multiple queues according to their priority. The dispatching of requests is done in a Merry-Go-Round fashion with a different slice of time for each queue.
Presently there are 6 types of queues the requests are parked in
[FONT=&quot]- [/FONT]High priority READ queue
[FONT=&quot]- [/FONT]High priority Synchronous WRITE queue
[FONT=&quot]- [/FONT]Regular priority READ queue
[FONT=&quot]- [/FONT]Regular priority Synchronous WRITE queue
[FONT=&quot]- [/FONT]Regular priority WRITE queue
[FONT=&quot]- [/FONT]Low priority READ queue
If in a certain dispatch cycle one of the queues was empty and didn't use its time, that queue will be marked as "un-served". For Ex. While in the middle of executing requests of Queue Y, a request comes to queue X (X having more priority over Y), and was un-served in the previous cycle. Then queue X will be preempted over queue Y. This won't restart the cycle. Once queue Y is done with its request, scheduler will go back to X, and allow it to finish it's request, before proceeding with resto fo the queues in the cycle.
For READ request queues idling is allowed to give the application(s) a chance to add more requests. The idling is enabled if the application is making requests in rapid succession.
ROW scheduler will support special services for memory cards that
support High Priority Requests. In addition it will support rescheduling of interrupted requests. For example, while working on a long write request, a sudden high priority read request comes in, the scheduler will inform the device and the device can stop the write request to serve the high priority read request. In such a case the device may send back the interrupted write request so that the scheduler will send it later according to the scheduler policy.
CFQ:
CFQ (Completely Fair Queuing) is similar to the Deadline. It maintains a scalable continuous Process-I/O The available I/ O bandwidth is used fairly and evenly to all I/O requests to distribute. It creates a statistics of blocks and processes. This is then used to guess when the next block is requested by what process, ie each process queue contains requests of synchronous processes, which in turn is dependent upon the priority of the original process. There is a second version with some fixes, such as allowing the request to starve, and some small search backward integrated to improve the responsiveness.
Benefits:
- It has the goal of a balanced I/O performance to deliver
- The easiest way one set
- Excellent on multiprocessor systems
- Best performance of the database after the deadline
Disadvantages:
- Some reported user that the media scanning would take very long time
- The fair and even distribution of bandwidth can cause delays in the boot process.
- Jitter (worst case delay) can be caused sometimes because of the number of competing with each other process tasks
BFQ:
Requests divided into time segments as the CFQ, but on a budget. The flash drive will be granted an active process until it has exhausted its budget (number of sectors on the flash drive).
Benefits:
- Has a very good USB data transfer rate.
- Be the best scheduler for playback of HD video recording and video streaming (due to less jitter than CFQ Scheduler, and others)
- Regarded as a very precise working Scheduler
- Delivers 30% more throughput than CFQ
FIOPS:
Fair, Efficient Flash I/O Scheduler is geared for the modern Flash based storage media well. I haven’t been able to find a lot of documentation for this. Will keep looking.
SIO:
It aims to achieve with minimal effort at a low latency I / O requests. Not a priority to put in queue, instead simply merge the requests. This scheduler is a mix between the noop and deadline. There is no conversion or sorting of requests.
Benefits:
- It is simple and stable. - Minimized Starvation for inquiries
Disadvantages:
- Slow random write speeds on flash drives as opposed to other schedulers. - Sequential read speeds on flash drives, not as good
V(R):
Unlike other scheduling software, synchronous and asynchronous requests are not handled separately, but it will impose a fair and balanced within this deadline requests, that the next request to be served is a function of distance from the last request. It is a very good scheduler with elements of the deadline scheduler. He will probably be the best for MTD Android devices. It also makes the most out of the benchmark points, but is also unstable scheduler, because its performance can fluctuates below or above average.
Benefits:
- Is the best scheduler for benchmarks
Disadvantages:
- Performance variability can lead to different results
- Very often unstable
ZEN:
This Scheduler is actually based on a combination of NOOP, SIO & VR Schedulers. This scheduler combines Synchronous & Asynchronous requests with same priority. It uses a deadline in order to derive or determine priority of a process.
FIFO:
First in First Out Scheduler. As the name says, it implements a simple priority method based on processing the requests as they come in.

4. I/O SCHEDULER ADJUSTMENTS
Ref -
https://www.kernel.org/doc/Documentation/block/
http://www.linux-mag.com/id/7572/
http://algo.ing.unimo.it/people/paolo/disk_sched/description.php
The Scheduler Adjustments are parameters that determine how the selected Scheduler behaves. Needless to say the list of parameters in this menu will change depending on which Scheduler you chose in the previous step. The screenshot depicts parameters for the ROW Scheduler. Even though there are quite a few Schedulers available in this kernel, parameters of some of them tend to be similar in effect. Hence I have combined the Schedulers whose parameters are similar.
​[FONT=&quot] Deadline, SIO and Zen: [/FONT][FONT=&quot]
fifo_batch: This parameter controls the maximum number of requests per batch.[/FONT][FONT=&quot]It tunes the balance between per-request latency and aggregate throughput. When low latency is the primary concern, smaller is better (where a value of 1 yields first-come first-served behavior). Increasing fifo_batch generally improves throughput, at the cost of latency variation. [/FONT]The default is 16.[FONT=&quot]
front_merges: A request that enters the scheduler is possibly contiguous to a request that is already on the queue. Either it fits in the back of that request, or it fits at the front. Hence it’s called either a back merge candidate or a front merge candidate. Typically back merges are much more common than front merges. You can set this tunable to 0 if you know your workload will never generate front merges. Otherwise leave it at its default value 1.
[/FONT][FONT=&quot]read_expire: In all 3 schedulers, there is some form of deadline to service each Read Request. The focus is read latencies. When a read request first enters the io scheduler, it is assigned a deadline that is the current time + the read_expire value in units of milliseconds. The default value is 500 ms.
write_expire: Similar to Read_Expire, this applies only to the Write Requests. The default value is 5000 ms.[/FONT][FONT=&quot]
writes_starved: Typically more attention is given to the Read requests over write requests. But this can’t go on forever. So after the expiry of this value, some of the pending write requests get the same priority as the Reads. Default value is 1.
This tunable controls how many read batches can be processed before processing a single write batch. The higher this is set, the more preference is given to reads.
CFQ
back_seek_max: The scheduler tries to guess that the next request for access requires going backwards from current position on the Disc. Given that such going back can be time consuming. So in anticipation, may move back on the disc prior to the next request. This setting, given in Kb, determines the max distance to go back. Default value is set to 16 Kb.
Do note that in a cellphone or tablet, the storage is actually Flash Memory technology. There is Disk head to be re-positioned. As such this is not that effective as backward reads are not that bad.
[/FONT][FONT=&quot]back_seek_penalty: This parameter is used to compute the cost of backward seeking. If the backward distance of a request is just 1 from a front request, then the seeking cost of the two requests is considered equivalent and the scheduler will not bias toward one or the other. This parameter defaults to 2 so if the distance is only 1/2 of the forward distance, CFQ will consider the backward request to be close enough to the current head location to be “close”. Therefore it will consider it as a forward request.
fifo_expire_async & fifo_expire_sync : This particular parameter is used to set the timeout of asynchronous requests. CFQ maintains a fifo (first-in, first-out) list to manage timeout requests. The default value is 250 ms. A smaller value means the timeout is considered much more quickly than a larger value. Similarly, fifo_expire_sync applies to the Synchronous requests. The default is 125 ms.
[/FONT][FONT=&quot]group_idle: If this is set, CFQ will idle before executing the last process issuing I/O in a cgroup. This should be set to 1 along with using proportional weight I/O cgroups and setting slice_idle to 0 as Flash memory is a fast storage mechanism.
group_isolation: If set (to 1), there is a stronger isolation between groups at the expense of throughput. If disabled, Scheduler is biased towards sequential requests. When enabled group isolation provides balance for both sequential and random workloads. The default value is 0 (disabled). [/FONT][FONT=&quot]
low_latency: When set (to 1), CFQ attempts to build a backlog of write requests. It will give a maximum wait time of 300 ms for each process issuing I/O on a device. This offers fairness over throughput. When disabled (set to 0), it will ignore target latency, allowing each process in the system to get a full time slice. This is enabled by default.
[/FONT][FONT=&quot]Quantum: This option controls the maximum number of requests being processed at a time. The default value is 8. Increasing the value can improve performance; the latency of some I/O may be increased due to more requests being buffered inside the storage.
[/FONT][FONT=&quot]slice_async: This parameter controls Maximum number of asynchronous requests at a time. The default value is set to 40 ms.[/FONT][FONT=&quot]
slice_idle: When a task has no more requests to submit in its time slice, the scheduler waits for a while before scheduling the next thread to improve locality. The default value is 0 indicating no idling. However, a zero value increases the overall number of seeks. Hence a Non-zero number may be beneficial.
slice_sync: This setting determines the time slice allotted to a process I/O. The default is 100 ms.
BFQ
timeout_sync & timeout_async: These parameters determine maximum disk time given to a task, respectively for synchronous and asynchronous queues. It allows the user to control the latencies imposed by the scheduler.
[/FONT][FONT=&quot]max_budget: This determines, how much of the queue request is serviced based on number of sectors on disc. A larger value increases the throughput for the single tasks and for the system, in proportion to the percentage of sequential requests issued. Consequence is increasing the maximum latency a request may incur in. The default value is 0, which enables auto-tuning
[/FONT][FONT=&quot]max_budget_async_rq: This setting determines number of async queues served for a maximum number of requests, before selecting a new queue.[/FONT][FONT=&quot]
low_latency: When this is set to 1 (default is 1), interactive and soft real-time applications experience a lower latency.
Row:
[/FONT][FONT=&quot]hp_read_quantum: Dispatch quantum for the high priority READ queue
rp_read_quantum: Dispatch quantum for the regular priority READ queue
hp_swrite_quantum: Dispatch quantum for the high priority Synchronous WRITE queue
rp_swrite_quantum: Dispatch quantum for the regular priority Synchronous WRITE queue
rp_write_quantum: Dispatch quantum for the regular priority WRITE queue
lp_read_quantum: Dispatch quantum for the low priority READ queue
lp_swrite_quantum: Dispatch quantum for the low priority Synchronous WRITE queue
read_idle: Determines length of idle on read queue in Msec (in case idling is enabled on that queue).
read_idle_freq: Determines the frequency of inserting READ requests that will trigger idling. This is the time in Msec between inserting two READ requests[/FONT]

5. CPU GOVERNORS –
THIS SECTION IS STILL IN PROGRESS. I WILL KEEP UPDATING.KINDLY BEAR WITH ME.
References -
http://androidforums.com/xperia-mini-all-things-root/513426-android-cpu-governors-explained.html
http://forum.xda-developers.com/showpost.php?p=28647926&postcount=1
http://pic.dhe.ibm.com/infocenter/l...ic=/liaai.cpufreq/TheConservativeGovernor.htm
http://lists.linaro.org/pipermail/linaro-kernel/2012-February/001120.html
A Governor performs a similar function for the CPU time management as the Scheduler. Originally, there were a set of Governors coming from the Linux kernel. Over the period, newer governors were introduced for Android architecture. Several developers added their own governors by modifying or tweaking existing governors.
​ To fully utilize the governors, you need to disable a file called mpdecision. It's located under /system/bin. It interferes with the governors operation and won't allow you to take full advantage of it's settings. Typically you can do this by renaming the file name using ES File Explorer and rebooting the phone. ​ Note that if you use the Touchwiz JELLYBEAN version, you should rename /system/bin/qosmgr to /system/bin/qosmgr.bak .
Essentially with either file, governor’s instructions for the second CPU are overridden. By renaming them, they are not loaded at Boot. So governor’s authority is restored.
ONDEMAND -
Reference - http://pic.dhe.ibm.com/infocenter/l...ic=/liaai.cpufreq/TheConservativeGovernor.htm
The ondemand governor dynamically changes CPU frequency in response to CPU utilization. It will automatically select the highest available processor frequency when the processor load rises above value set by up_threshold. If CPU utilization rises above the up_threshold parameter, the ondemand governor increases the CPU frequency to scaling_max_freq. When CPU utilization falls below this threshold, the governor decreases the frequency in steps to run at the next lowest frequency until it reaches scaling_min_freq. After each sampling_rate milliseconds, the current CPU utilization is reexamined and the process is repeated dynamically to adjust the CPU frequency per process load. Since the governor needs time to respond, performance might be reduced if the usage changes frequently.
CONSERVATIVE –
Reference- http://pic.dhe.ibm.com/infocenter/lnxinfo/v3r0m0/topic/liaai.cpufreq/TheConservativeGovernor.htm
This governer prefers the lowest possible clock speed as often as possible. Only upon a larger persistent load on the CPU will the conservative governor raise the CPU clockspeed.
This will tend to try and keep the CPU running at lower speeds and consequently lower voltage. This inherently will conserve the battery.
Like the Ondemand governor, it steps the CPU through the operating frequencies by dynamically adjusting frequencies based on processor utilization. However, the conservative governor increases and decreases CPU speed more gradually as against the hair trigger response of OnDemand governer. This governor increases the frequency step by step upon CPU load but jumps to lowest frequency when the CPU load is removed. Thus it aims to dynamically adjust the CPU frequency to current utilization, without jumping to max frequency. If CPU utilization is above up_threshold, this governor will step up the frequency to the next highest frequency below or equal to scaling_max_freq. If CPU utilization is below down_threshold, this governor will step down the frequency to the next lowest frequency until it reaches scaling_min_freq. After each sampling_rate milliseconds, the current CPU utilization will be reexamined and the same algorithm will be applied to dynamically adjust the CPU frequency to current utilization.
Note - Depending on how the developer has implemented this governor, and the minimum clockspeed chosen by the user, you may experience some choppiness or random freeze. So you need to choose its settings more judiciously.
KTOONSERVATIVE –
As I said earlier, Ktoonservative is a Hotplug derivative of the traditional Conservative Governor. Hot plugging allows the governor to turn off second core of the processor dynamically. This maintains a healthy balance of Performance and Battery life.
I wish to respectfully quote @freecharlesmanson.
Ondemand scales to the highest frequency as soon as a load occurs. Conservative scales upward based on the frequency step variable which means for the most part will scale through every frequency to achieve the target load thresholds. What this practically means is ondemand is prone to wasting power on unneeded clock cycles. Ondemand also features something called a down differential, this variable determines how long the governor will remain at the given frequency before scaling down. Conservative does not have this, but instead relies on having a down threshold which insures that as soon as the load drops below a given variable it scales down as fast as the sampling rate allows. The result to this is a governor which attempts to keep the load level tolerable and save you battery! Now ! Ktoonservative Is that but in addition contains a hotpluging variable which determines when the second core comes online. The governor shuts the core off when it drops below the hotplug down threshold thus giving us a handle on the second performance factor in our CPUs behavior. While by default conservative is a poor performer it can be made to perform comparably to even performance governor. Here are some settings to discuss and start with. They are slightly less battery friendly under a load but very very well performing.
Click to expand...
Click to collapse
SMARTASSH3 –
This is a balanced governor that tries to balance between Performance and Battery life. This governor is based on the SmartassV2 Governor. Since it was tweaked by H3ROS, the name is modified. The V2 in turn is a derivative of the original SmartAss governor. It tries to attain an Ideal frequency by ramping up to that frequency quickly. Once reached, further ramping is done very slowly. This Ideal value is user defined in the Governor settings.
The governor also has different frequencies for Screen ON and Screen OFF states along with Sleep state.
NIGHTMARE -
This is one of the newer Performance oriented governor. It tries to reach the top frequency by scaling rapidly. Once reached, it tries to maintain the frequency as much as possible. It is based on the PegasusQ governor.
It is multi-core version of the Ondemand governor with integrated hot-plugging. Ongoing processes in the queue can run simultaneously . These processes are in a “Run Queue" queue that is ongoing. The processes are arranged according to their priority values. To ensure that each process has its fair share of resources, each is run for a certain period and then stops and placed in the queue for next turn. This continues until the processes are terminated.
DANCEDANCE –
This governor is based on the Conservative Governor. It was created by Snuzzo by modifying Ramp up rate to be higher as well as Sleep routines.
WHEATLEY –
This one took some digging as Wheatley is not a Linux Governer brought to Android. XDA Developer @phone_user implented this governer for his Samsung Galaxy Nexus Kernel.
In essence, this governer takes on a novel approach to power saving. As you may deduced so far, making the CPU operate at lowest needed frequency (like conservative does), can potentially backfire with CPU taking more time (and more consumption over time) to finish the task. So Wheatley actually targets the CPU Frequencies and its Deep Sleep State (AKA C4 State). In this state, the CPU voltage is reduced to avoid unnecessary power consumption.
So respectfully quoting him for the details.
phone_user said:
The previous benchmarks of the usage of the C4 state for different activities have shown that for 'light' tasks like browsing the internet, reading (for example emails or eBooks) and the average app the device spends about 40% of the time in C4 with acceptable average residencies of around 11ms. For more demanding tasks like games and video playback the C4 state is still being used however the efficiency is reduced due to the low average residencies of below 5ms (considering that the wakeup latency is 1.3ms).
I have run a few tests and as it turns out, for demanding tasks the efficiency of the C4 state is significantly reduced due to these low residency times (= large number of wakeups) to a point that the good old frequency scaling is indeed more efficient with larger battery savings. So unfortunately, relying on the C4 state alone for power savings for all tasks is not a good option.
However, unfortunately we also cannot simply use one the available standard governors since always try the minimize the frequency without taking account that this behaviour diminishes the efficiency of the C4 state since it hinders a proper race-to-idle. So taking advantage of this knowledge what a good governor should do, is using the maximum frequency whenever the C4 state is properly used with acceptable average residencies and only scale down when the average residencies get too low (or the C4 is not used at all, of course).
Building on the classic 'ondemand' governor I implemented this idea in my new Wheatley governor. For internet browsing the time spend in C4 has increased by 10% points and the average residency has increased by about 1ms. I guess these differences are mostly due to the different browsing behaviour (I spend the last time more multi-tabbing). But at least we can say that Wheatley does not interfere with the proper use of the C4 state during 'light' tasks. For music playback with screen off the time spend in C4 is practically unchanged, however the average residency is reduced from around 30ms to around 18ms, but this is still more than acceptable.
So the results show that Wheatley works as intended and ensures that the C4 state is used whenever the task allows a proper efficient usage of the C4 state. For more demanding tasks which cause a large number of wakeups and prevent the efficient usage of the C4 state, the governor resorts to the next best power saving mechanism and scales down the frequency. So with the new highly-flexible Wheatley governor one can have the best of both worlds.
Click to expand...
Click to collapse
ABYSSPLUG –
This is a Modifed version of the Hot Plug Governer. It is similar to the On Demand governor, but is more accurate steps through CPU frequencies depending on CPU load. Like the Hotplug governor, it turns off unused CPU cores upon low CPU utilization.
BADASS –
ASSWAX –
SlP –
PEGASUSQ –
ADAPTIVE –
INTERACTIVE –
This governor is designed for latency-sensitive workloads, such as interactive user apps. The interactive governor aims to be significantly more responsive to ramp CPU quickly up when CPU-intensive activity begins.
Existing governors sample CPU load at a particular rate, typically every X ms. This can lead to lag from the time user begins interacting with a previously-idle system until the next sample period.
The Interactive governor, instead of sampling the CPU Load, it will check whether to scale up CPU frequency immediately after CPU becomes active. This is done with a timer, that triggers within 1-2 ticks. If the CPU is very busy after becoming active, then the governer assumes the CPU to be underpowered and will ramp to MAX speed. If the CPU was not sufficiently busy to immediately ramp to MAX speed.
After this, the governor evaluates CPU load, choosing the highest value between longer-term load or the short-term load since idle exit to determine the CPU speed to ramp to.
A realtime thread is used for scaling up, giving the remaining tasks the CPU performance benefit. This is unlike existing governors which are more likely to schedule other tasks to occur after your performance starved tasks have completed.
USERSPACE -
This governer allows for more granular control over Power policy for the device. It allows any user apps to set the processor frequency. It does not dynamically change the CPU frequency or react to processor load, rather it only provides a mechanism to set the frequency through the use of the scaling_speed parameter. However, KT747, does not implement any tunable parameters for the user.
POWERSAVE -
As the name says, the only priority for this governer is to provide power saving with no regard for apps being slowed down. This can be counter intuitive since slowed down apps will take even longer time and thus drain battery further.
It sets the CPU to the value of the scaling_min_freq parameter. (Default value is the lowest available processor frequency). However, KT747 does not offer this parameter as a tunable within the KTweaker application.
PERFORMANCE -
As the name says, this governor exclusively focuses on providing consistent minimum latency. This governor sets the CPU speed to the highest available frequency. The CPU speed is always set to the frequency defined in scaling_max_freq parameter. (Default is the highest available processor frequency). However KT747 does not expose this setting via the KTweaker application.

6. CPU GOVERNOR ADJUSTMENTS
Governor Adjustments are typically parameters for a given governor that you can further tweak. There are certain Performance Scripts out there that may set some of these parameters as well. One such example is System Performance Mod Thunderbolt! By @pikachu01​
Given below are some of the parameters of commonly used Governors. There are quite a lot of parameters for each governor. Having to list each one will be pretty intensive. I may choose to add these in future as time permits AND if there is a demand for it. In addition, I am adding Hide tags for each governor in order to tidy up the post.
ONDEMAND GOVERNER-
Ignore_nice_load - You can use the ignore_nice_load option to ignore all processes, that run with a positive nice value. These will not be counted toward the overall CPU utilization. Set this parameter to 1 if you do not care how long it takes for such processes to complete.
sampling_rate - Measured in us. , this is how often the kernel look at the CPU usage and make decisions on what to do about the frequency. Higher values means CPU polls less often. For lower frequencies, this could be considered an advantage since it might not jump to next frequency very often, but for higher frequencies, the scale-down time will be increased.
up_threshold - Measured in percentage 1-100, When CPU load reaches this point, governor will scale CPU up. Higher value means less responsiveness and lower values corresponds to more responsiveness at the cost of battery.
powersave_bias - Default value is 0. Setting a higher value will bias the governor towards lower frequency steps. Use this if you want CPU to spend less time on higher frequencies. A better alternative would be to underclock to a lower frequency than using powersave bias.
The powersave_bias parameter modifies the behavior of the ondemand governor to save more power by reducing the target frequency by a specified percentage. By default, the it selects the minimum processor frequency that can still complete a workload with minimal idle time. Doing so should result in the highest performance to power efficiency ratio. In some cases, you might prefer a greater emphasis on power efficiency than performance. In this case, set the powersave_bias parameter to a value between 1 and 1000 to reduce the target frequency by one-thousandth of that value. Say if you set powersave_bias to 100 it will cause a one-tenth reduction in target frequency. If the Max frequency of the device is 2 GHz, the governor instead will request 1.8GHz – a one-tenth reduction. If 1.8 GHz is an exact match with an available hardware frequency (listed in the scaling_available_freq parameter), the processor is set to this frequency. If 1.8 GHz is not available, the processor fluctuates between the closest available upper and lower frequencies for an average frequency of 1.8 GHz. The default value is 0.
sampling_down_factor - In the simplest form, sampling_down_factor determines how often CPU should stay at higher frequencies when truly busy. Default behavior is fast switching to lower frequencies (1). Having sampling_down_factor set to 1 makes no changes from existing behavior (for the non-modified ondemand), but having sampling_down_factor set to a value greater than 1 causes it to act as a multiplier for the scheduling interval for re-evaluating the load when the CPU is at its highest clock frequency (which is scaling_max_freq) due to high load. This improves performance by reducing the overhead of load evaluation and helping the CPU stay at its highest clock frequency when it is truly busy, rather than shifting back and forth in speed. This tunable has no effect on behavior at lower frequencies/lower CPU loads.
down_differential - This factor indirectly calculate the 'down-threshold' of Ondemand. After completing sampling-down-factor*sampling-rate at max frequency because of high load, governor samples the load again to calculate an estimate of the new target frequency in a way that the lowest frequency will be chosen that would not trigger up_threshold in the next sample. Because triggering up-threshold will again cause CPU to scale up to max frequency. During this choice down_differential is taken into account as a breathing room value. Target frequency is calculated as max_load_freq / (up_threshold - down_differential). The obtained value might be a non-existent value in the freq_table and CPU driver will round it off to a value in freq_table. max_load_freq is the theoretical frequency at which CPU can handle 100% workload. It is usually a value below scaling_max_freq. See this post by AndereiLux for more info.
freq_step - Whenever up-scaling logic is triggered the governor instructs the CPU to raise its frequency by freq_step percentage of max allowed frequency. (max policy * (freq step / 100)). Ex: max policy is 1600 and freq step 21%, it will scale 1600 * 21% = 336. We have a 100MHz grained frequency table so it rounds up to the next 100MHz, hence 336 becomes 400. So say we're idling at 200MHz and the up-scaling logic gets triggered with the above settings, the next frequency will be 600MHz. Note that freq_step and smooth_scaling does pretty much the same thing.
SMARTASSV2 GOVERNER –
awake_ideal_freq - The frequency until which CPU is scaled up rapidly on screen-awake (from sleep). Thereafter, scaling up is less aggressive.
sleep_ideal_freq - The frequency until which CPU is scaled down rapidly when screen is turned off. Thereafter, scaling down is less aggressive.
up_rate_us - The minimum amount of time to spend at a frequency before we can ramp up. (Ignored below awake-ideal frequency since governor needs to rapidly scale up to awake_ideal_freq when below it)
down_rate_us - The minimum amount of time to spend at a frequency before we can ramp down. (Ignored above sleep-ideal frequency since governor needs to rapidly scale down to sleep_ideal_freq when above it)
max_cpu_load - Same as up_threshold in other governors.
min_cpu_load - Same as down_threshold in other governors.
ramp_down_step - Frequency delta when ramping down below the ideal frequency. Zero disables and will calculate ramp down according to load heuristic. When above the ideal frequency we always ramp down to the ideal freq.
ramp_up_step - Frequency when ramping up above the ideal frequency. Zero disables and causes to always jump straight to max frequency. When below the ideal frequency we always ramp up to the ideal freq.
sleep_wakeup_freq - The frequency to set when waking up from sleep. When sleep_ideal_freq=0 this will have no effect.
KTOONSERVATIVE & CONSERVATIVE GOVERNER-
Boost_2nd_Core_On_Button -
This configuration option when set, allows you to turn the second Core ON with Back+Home+Menu button combo.
Boost_CPU - @KToonsez hasn't documented much on this setting. But based on my experiments, I feel that this, specifies the frequency to which the second Core is set when turned on by the button combo above.
Boost_GPU - Similar to Boost_CPU, this will set the frequency of operation of the GPU when the second core is turned on.
Boost_Hold_Cycles -
This setting specifies the duration for which the Core 2 will be kept on. A value of 22 translates as 1 second.
Boost_Turn_on_2nd_Core -
When set, this setting will make second core turn on immediately on touch.
CPU_Down_Block_Cycles -
This setting is used to counteract the effects of hot plugging. It specifies duration for which the CPU Cycles are throttled before hot plugging the second core out.
Disable_Hotplug_BT -
As the name suggests, when set. this setting will stop the second core from being turned off when Bluetooth connection is active.
Disable_Hotplugging -
When set the entire process of hot plugging is turned off.
freq_step - Defines how much (as a percentage of the maximum CPU speed) the conservative governor will increase the CPU speed by each time the CPU load reaches the Up Threshold.
sampling_down_factor & sampling_rate- The sampling_down_factor value acts as a negative multiplier of sampling_rate to reduce the frequency that the scheduler samples the CPU utilization. For example, if you set sampling_rate to 10,000 and sampling_down_factor to 2, the scheduler samples the CPU utilization every 20,000 microseconds.
freq_step - The freq_step parameter changes the size of the frequency step that the governor uses to change CPU frequency in either direction. By default this setting is 5, which means the governor will change the CPU frequency by five percent of the maximum or minimum frequency each time it changes frequencies. If you set this value to 100, the governor will behave exactly like the ondemand governor and immediately increase to the highest speed.
ignore_nice_load - You can set the ignore_nice_load option to ignore all processes that run with a positive nice value will not be counted toward the overall CPU utilization. Hence will not cause the CPU frequency to increase and might take longer to complete. When set to 0 (the default), all processes are counted toward the CPU utilization value. When set to 1, niced processes are ignored.
No_2nd_CPU_Screen_Off -
As the name says, setting this to 1 (default value), will turn off second core on your device. For those with more than 2 cores, there will be corresponding settings for 3rd and 4th core.
Sampling_Down_Factor - This parameter controls the rate at which the
kernel makes a decision on when to decrease the frequency while running
at top speed. When set to 1, decisions to re-evaluate the CPU load, are made at the same interval regardless of current clock speed. But when set to greater than 1 (e.g. 2 Default value) it acts as a multiplier for the scheduling interval for reevaluating load when the CPU is at its top speed due to high load.
This improves performance by reducing the overhead of load evaluation and helping the CPU stay at its top speed when truly busy, rather than shifting back and forth in speed. This tunable has no effect on behavior at lower speeds/lower CPU loads.
Sampling_Rate - This is measured in uS (10^-6 seconds). That is how often the kernel will poll the CPU usage and make decisions on what to do about the frequency. It's default value is 25000.
Sampling_Rate_Min - As the name states, this value provides a minimum limit on the Sampling_Rate. This is based on the Hardware Latency and Kernel variables. Default value is 10000.
Sampling_Rate_Screen_Off - As the name suggests, this is the value of Sampling_Rate when the screen is turned off. Default Value 40000.
Up_Threshold - It specifies what the average CPU usage between the samplings of 'sampling_rate' needs to be for the kernel to determine if it should increase the frequency. For example when it is set to '70', between the checking intervals the CPU needs to be average more than 70% in order to determine that the CPU frequency needs to be increased.
Up_threashold_Hotplug - As the name suggests, this value determines when to bring the second Core Online. It is done when the CPU load reached this %.
INTERACTIVE GOVERNER-
hispeed_freq - An intermediate "hi speed" at which to initially ramp when CPU load hits the value specified in go_hispeed_load. If load stays high for the amount of time specified in above_hispeed_delay, then speed may be bumped higher. Default is maximum speed.
Above_hispeed_delay - Once speed is set to hispeed_freq, wait for this long before bumping speed higher in response to continued high load. Default is 20000 uS.
go_hispeed_load - Go to hi speed when CPU load at or above this value. (Similar to Up-Threshold in other governors). The CPU load at which to ramp to the intermediate "hi speed". Default is 85%.
min_sample_time - The minimum amount of time to spend at the current frequency before ramping down. This is to ensure that the governor has seen enough historic cpu load data to determine the appropriate workload. Default is 80000 uS.
timer_rate - The sample rate of the timer used to increase frequency. It reevaluates cpu load when the system is not idle. Default is 20000 uS.
input_boost: If non-zero, boost speed of all CPUs to hispeed_freq on touchscreen activity. Default is 0.
boost: If non-zero, immediately boost speed of all CPUs to at least hispeed_freq until zero is written to this attribute. If zero, allow CPU speeds to drop below hispeed_freq according to load as usual.
boostpulse: Immediately boost speed of all CPUs to hispeed_freq for min_sample_time, after which speeds are allowed to drop below hispeed_freq according to load as usual.
WHEATLEY GOVERNER -
target_residency - The minimum average residency in µs which is considered acceptable for a proper efficient usage of the C4 state. Default is 10000 = 10ms.
allowed_misses - The number sampling intervals in a row the average residency is allowed to be lower than target_residency before the governor reduces the frequency. This ensures that the governor is not too aggressive in scaling down the frequency and reduces it just because some background process was temporarily causing a larger number of wakeups. The default is 5.

VOLTAGES SECTION –
This Section lists all the possible Operating Frequencies of the Processor of the phone. The Mili Volt (MV) define the operating power in Volts of the Processor at that frequency. Some basic facts for you to understand. The Frequencies determine how fast the Processor will be operating. The voltages determine Juice provided to the processor. As a processor consumes higher voltage, it will generate more heat. So this section is very important and critical to everyone who wishes to either Overclock or Undervolt. ​Overclocking is a term used to determine how the operating Frequencies are controlled in order to obtain maximum performance and fastest response time. As we saw in the General Section, the Enable Overclock checkbox allows you to push the boundaries of the operating frequencies. So the processor will offer better performance, but will also generate more heat due to higher operating voltages. So in this section you will need to cool down the processor by applying lower operating voltage. This however should not be confused with undervolting.
Undervolting is a concept that is used to obtain highest amount of Battery life. As the operating voltage is the major consumer of the battery, lowering operating voltages in steps of 25 will allow the processor to operate at that frequency with a possible Lag. Weather you do notice the lag or not is dependent on how much the voltage is lowered. It is also dependent on the Max & Min Operating frequencies you chose in the General Section.
Having said that, on this screen, you can press the menu button to get a new menu. This menu will allow you to modify voltages set at each frequency step.
The option to Load Stock table allows you to reset to Default voltage values in case you wish to revert. Rest of the options to add or Subtract will let you change all steps in bulk. So for ex. the option to add 5 Volts to all steps will add 5 mv to current voltage for that step. The settings option does not seem to do anything.
[FONT=&quot]NOTE – Even though the options are in VOLTS, they should read Milli Volts.[/FONT]​

EXTRAS -
Eventhough this is called EXTRA, it actually has quite a few important options. Chief among these, is the ability to set different Governors under certain circumstances as well as setting a different upper limit on frequency.
SCREEN OFF PROFILE Mhz –
As the name says, this determines the upper limit on Operating Frequency when the Screen is Off. Thus it will override what you set on General screen. This is good to have if you want the frequency further throttled when you are not using or just have different frequency for background apps when not using.
NOTE – If you set screen turn off time too low, and the screen turns off when you are reading something; you will have unexpected consequences. Not to mention battery or smoothness hit.
DISABLE SCREEN OFF Mhz CALL –
This is a further addition to the Screen off Profile discussed above. When set, this option will apply the Screen Off Profile when you are on a call. Thus applying the frequency you set in the previous option. So you need to do this carefully in order not to get your phone unresponsive or FC’d in the middle of a call.
SCREEN OFF PROFILE GOV. –
As the name says, you get to set a different governer when screen is off. This will override what you chose in the governer choice. Pretty nifty arrangement so that you can flip from a performance governer when on screen and a power save governer when screen is off. Keep in mind the time out screen off when you are reading without interacting.
SCREEN OFF PROFILE SCHED –
Similar to the Governer, this will let you choose a different Scheduler for when the screen is off. This will override (when screen is off) what you set previously.
GPS PROFILE GOV –
Similar to Screen off, this will set a Governer choice that comes into play when you are navigating or have the GPS on. If, some of you tend to keep the GPS on permanently then keep in mind that your main choice of governer will be permanently overridden.
GPS PROFILE SCHED –
Similar to the Governer, you get to choose which Scheduler comes into play when you are navigating. Keep in mind that, during navigation, the phone will keep reading from the Google Map Cache or any other Navigation product you may be using. So choose Scheduler appropriately.
BLUETOOTH PROFILE MHZ –
This setting determines the MINIMUM operating frequency when the phone is paired over Bluetooth to another device. This is unlike the Screen off option where the Max frequency is determined.
FAST CHARGING –
One of the coolest feature of the Kernel. When set, the phone will charge off of the PC USB ports as if it is connected to wall outlet. This does turn off your access to the phone internal memory and SD card. If you want to access the internal storage on PC then you have to turn this off.
NOTE – Weather to turn on or off, has to be done before connecting to PC. Changing this after connecting has no effect.
VIBRATION STRENGTH –
This Kernel parameter is actually a multiplier. It actually determines the intensity of vibration when the phone is in vibrate mode or ring Plus Vibrate Mode. It also determines vibrations of the notifications you receive. (It is possible it also determines In-App or In-Game vibrations. I did not test). It’s a good thing to control as some of the roms have very low vibration intensity out of box. Do note that vibrations do chew up your battery. So don’t set it too high. Based on my experiments, the out of box setting at 120 seems good enough.
SWIPE 2 WAKE –
This is an Interesting concept. If this is set, then you get to short circuit the process of waking the phone. What you need to do is slide through the capacitive buttons on your phone as if you are sliding the screen to unlock. This bypasses the step where you press power or home button to wake to lock screen and then actually unlock the phone.
Given that my phone SGH-T999 does not have all Capacitive buttons, it does not seem to work. Besides I have secured pin on my lock screen so it won’t unlock by this method either. (I don’t find it that useful either.)
INTERNAL READ AHEAD, EXTERNAL READ AHEAD –
Both of these parameters control the size of the buffer. Internal refers to your Internal SD Card & External refers to the MicroSD card. Do note, the buffer resides in RAM. So if you set it too high then you won’t have free RAM to play with. Also This must be used with a judicious choice of the Scheduler.
GPU GOVERNER –
This is probably of interest only to the gamers or Graphic intensive app users. Similar to the previous governer choices for CPU, this option allows you to further tweak the Governer choice for your GPU. It only affects the Graphics displayed. So unless you have graphic intensive app running, you won’t notice the difference. By default it will use the Governer set for the CPU.
TRINITY COLORS –
This of this, like the Gamma control on your TV or a monitor. This determines the basic color pallet on your phone. Think of it as if you applied a color filter to the screen. Based on what value you set here, effect will be immediate.
CONGESTION CONTROL –
First of the TCP/IP network performance parameter. TCP Congestion Control determines which algorithm is applied for the network congestion avoidance. You have two choices. Cubic & Reno. Cubic is less aggressive and Reno is more aggressive. Suffice it to say that pretty much every one will have their own performance. So there is no recommendation. For the more geeky minded, here’s the Wikipedia link.
TIME WAIT RECYCLE –
Second of the TCP/IP network performance parameter. This parameter determines, how long will the system wait before it will recycle a connection in wait state. It will benefit those on Wireless or high speed data plans. Default is Enabled. So if you have perennial bad performance on high speed connection, you can turn it off.
TIME WAIT REUSE –
Third of the TCP/IP network performance parameter. Similar to Recycle above, this too controls the time before the system reuses a connection. This too is set to Enable. Turn it off if you have connectivity issues.
SHOW TOAST MESSAGES –
This controls weather Kernel response messages are displayed on screen. These are either for the automated actions or response to changes you made. Default is enabled.
ENABLE KTWIDGET TIMER –
To be honest, I have no idea what this does. If someone is willing to share, I will be more than happy to add.
BATTERY MHZ CONTROL –
This actually has its own sub menu. Effectively it allows you to throttle down the CPU frequency if the battery is too low or is high. You also get to define what is the low level and what is the high level. Lastly, you can turn it off while charging.
NOTE – This has a direct conflict with what frequencies you have set on the main screen. So use judiciously.
KTHERMAL CONTROL –
This too has its own sub menu with several options. Effectively it allows you to throttle down the CPU and GPU in case the phone has heated, as the warning correctly says on the submenu, if you don’t set it correctly, you will damage the processor.
The options are pretty much self explanatory. Just to keep the noobs from killing their phones, I am not explaining each option. If there is high demand, I will add individual description here.
GET LAST_KMSG, GENERATE A DMESG, GENERATE A LOGCAT –
[FONT=&quot]All three of these are KTOONSEZ’s way of grabbing error messages in case stuff happens. These are saved as text files on your internal sd card. You will only need these options if you are trying to identify a possible kernel issue.[/FONT]

SET OPTIONS ON BOOT -
This option allows you to choose when to apply the settings you have provided here. You may apply them immediately after booting or wait for some time before applying. If you are testing some exotic setting, choose to apply with delay so that you have time to revert to stock.
BACKUP PREFS TO SDCARD –
Pretty much self explanatory. It exports the settings to internal SD Card under the path you specify.
RESTORE PREFS FROM SDCARD –
Same as above, allows you to restore settings previously exported.
LOAD DEFAULTS –
Allows you to set default values of the kernel. These are the values, KTOONSEZ has set for the kernel. Safe spot to run to if you managed to mess up the settings.
That pretty much concludes all the options on the KTweaker app.

RECOMMENDED SETTINGS -
This section is intended to provide basic stable profiles that have been tested repeatedly. These profiles would help beginners to get started in the direction they wish to go. Of course they may not be the best in that class. But then no two phones are same so what works for one may not work for others.
Note-
For those who wish to further Battery life, you may do well to visit this thread on Eliminating Google Services Wakelock.
The general process for using these files is as follows.
1. Download the file(s) to your phone. In case of .BIN files, optionally rename as .TXT
2. Copy the file(s) to /SDCARD/KTweaker folder with file Manager of your choice.
3. Open Ktweaker app, click on Import Settings.
4. The file you just copied should be listed there.Choose the one you want to apply.
5. After applying, make sure Set Options on Boot Setting on main Menu of the KTweaker app has a little green text bellow confirming that the settings will be applied upon reboot.
6. Profit !
If you are hungry for more or wish to tinker further, head over to the Team Kernerlizer Threads. Links are given bellow. (Hidden in order to tidy up the thread.)[/COLOR]
Team Kernalizer Galaxy SIII threads by Carrier -
Team Kernalizer Thread for T Mobile Galaxy SIII / D2TMO - Thread Link
Team Kernalizer Thread for Sprint Galaxy SIII / D2SPR - Thread Link
Team Kernalizer Thread for AT&T Galaxy SIII / D2ATT - Thread Link
Team Kernalizer Thread for Verizon Galaxy SIII / D2VZW - Thread Link
Given bellow are some of the tried and tested profiles.
1. Conservative Battery Saver Profile -
Conservative Balanced Settings by @LuigiBull23
Settings File is for AOSP version of the Kernel. Attached to this post - ROW-Balanced_Bull_v2.txt
The battery life for him with these settings can be seen bellow.
I on the other hand had a little bit better luck with my light to moderate use. (Hidden to tidy up the thread).
NOTE - I had accidentally connected the phone to Laptop for a minute or 2 when Battery was at 12 % (Fast Charge was ON).
Do Please note, there is an additional experimental profile called Bless the Child V3 by @LuigiBull23 that Ihave attached bellow. Try if you wish. I will post the results of my test after next Charge Cycle.
LuigiBull23 said:
ROW Balanced Bull v3​
***Reported to have resolved issues with battery drain, overheating, and random reboots!***​
General
Locked Frequencies
CPU (MIN): 135Mhz
CPU (MAX): 1404Mhz
Scheduler: ROW
Scheduler Adjustments:
> hp_swrite_quantum = 3
> low_starv_limit = 8000
> rd_idle_data = 5
> rd_idle_data_freq = 15
> reg_starv_limit = 4000
> rp_swrite_quantum = 2
> rp_write_quantum = 2
Governor: Ktoonservative
Governor Adjustments:
> boost_cpu = 1026
> boost_hold_cycles = 18
> boost_turn_on_2nd_core = 0
> down_threshold = 58
> down_threshold_hotplug = 65
> freq_step = 2
> sampling_down_factor = 2
> sampling_rate = 25000
> sampling_rate_screen_off = 40000
> up_threshold = 70
> up_threshold_hotplug = 80
Voltages
CPU: -30mV across the board
GPU: -50mV across the board
Extras
Screen Off Profile Mhz: 378
Screen Off Profile Gov: Same as selected governor
Screen Off Profile Sched: Same as selected scheduler
Miscellaneous Section:
> Vibration Strength: 60
SD Card Section:
> Internal Read Ahead = 2048
> External Read Ahead = 2048
Battery Mhz Control:
> Battery Level Low: 20
> CPU Mhz for Low Level Battery: 1080Mhz
[/CODE]
Click to expand...
Click to collapse
2. Extreme UNDERVOLTING PROFILE -
Extreme Undervolting without Lag by @iamikon
iamikon said:
Forget that try this! SIO-NoCleverName-AOSP
http://db.tt/3dcMQCz0
Click to expand...
Click to collapse
NOTE - You may need to up voltage by 50 mV if you continue to experience lag or Freeze.
Settings File for AOSP Version of the Kernel is attached - sionoclevernameaosp.txt
3. Gamer (Or Game intensive) PROFILE -
Thanks to @RErick, here's a good stable setup for those who wish to play Graphic Intensive (Shadowgun DeadZone ) games on their phones.
Obviously, you won't be expecting outstanding battery life with intense gaming. (Can I get Prius Gas Mileage from a Corvette ?) But if you do, @RErick has graced us with this Profile. Do note this second profile may potentially lag under heavy Graphics.
But

@Perseus71
http://lwn.net/Articles/509829/
Info on ROW scheduler

castle_bravo said:
@Perseus71
http://lwn.net/Articles/509829/
Info on ROW scheduler
Click to expand...
Click to collapse
Thanks Castle. Appreciate the link.

It's about damn time!! lol I've been waiting for a guide like this that works in correlation to the Ktweaker app.. It will definitely benefit to newcomers as well as current users of this kernel.
Great guide! Thanks buddy :good:

Great guide, excellent work! Subscribed!

Great work my friend will be adding this to all the tk threads if you ever need anything just give a buzz we would glad to help anyway possible and again great write up amd guilde very informative
http://pbr1202.photobucket.com/albums/bb374/TexasEpic/Requested Banners/SPH-L720v3_zps61b75aad.png

Look good friend. Keep up the good work. I will link in my threads too

Hi nice work there, but is there any latest settings for tw version ? Or have i missed it ?

Rayfucious said:
Hi nice work there, but is there any latest settings for tw version ? Or have i missed it ?
Click to expand...
Click to collapse
I personally use AOSP Roms. So I can't translate them to Touchwiz. However, I have given the individual setting Values for the Balanced Profile. You can enter these values into KTweaker to get the file.

Perseus71 said:
I personally use AOSP Roms. So I can't translate them to Touchwiz. However, I have given the individual setting Values for the Balanced Profile. You can enter these values into KTweaker to get the file.
Click to expand...
Click to collapse
So i can enter the above values into TW version and compatible ? cause i thought aosp kernel settings and tw would be different.
Can't find this 2 settings in ktweaker for tw version though.
up_threshold_hotplug = 80
down_threshold_hotplug = 62
The rest are fine though. Will be trying out and see how it goes.

[BATTERY GUIDE] Ultimate battery guide and talk topic

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Ultimate battery guide
Battery, one of the most important thing on todays phones. Even if we have awesome battery life we always want more and it is never enough.
This is the small guide to tips, trick and tweaks to improve battery life.
This topic is to share tips and tricks and basically just small talk about battery and sharing screenshots.
Use Gsam or Android battery history to show your battery life.​
Our goal is to make most of the screen on time with average use of 24 hours. So lets start.
Post 1: Tips
Post 2: ROMS, kernels, undervolting, underclocking
Tips to improve battery life
Location services
One of the first thing that your device will ask when you are setting up your phone. Most of the users let them ON and just forgot about them. Location services are battery hungry and the will drain your battery like you drinking juice.
Thing is that you do not need them always, just sometimes. Turn it OFF then. I have them turned off always and when I need it I just simple turn it ON.​
Wi-Fi
Wi-Fi scanning is thing that will drain your battery always. When you are out and you are not expecting to use wi-fi any time soon turn it off. You do not need to run scanning all the time.
You could also edit build.prop to reduce.
Edit wifi.supplicant_scan_interval. Default value is 180. You can set it higher to reduce the scanning intervals.​
Signal strength / Network mode
Signal strength is always trouble for battery. Weak signal will drain more battery. Also, constant changing between 4G/3G and 2G will drain battery faster.
Tweak to this is to set your phone to only use 2G, 3G or 4G.
Example: when I am not using my phone, or it is connected to wifi my network is on 2G. I dont need 3G or 4G then and changing network state is disabled then because it will stay always on 2G. I found it has positive effect on battery.
When I need, I just simple toggle 3G or 4G.​
Screen brightness
Screen is the thing that drains most of our battery. There is not much philosophy here. Higher brightness will drain more battery.
My personal setup is that I do not use auto brightness. I always change brightness manually. Right now during winter my brightness does not go more then 25% outside, and inside it is lower. At night it is under 10%.
I found that not using auto brightness has also slight positive effect on battery.​
Syncing / Airplane mode / Vibration / Animations / Task Killers
Lets start in order.
Syncing: more syncing your device does it drains more battery. On your phone probably you do not to sync all accounts and apps you have every few minutes or hours. Set those apps you do not need on manual sync.
Airplane mode: I am using airplane mode during night because I do not want to be disturbed during sleep. With airplane mode battery consumption during night is 0%. Yes, zero percent.
Vibration: more your device vibrates, more battery it drains. You can reduce vibrations on keyboard settings and similar. I found that is not much effect on battery but it has slight.
Animations: animations drains your battery also and who really needs them. Personally, I am annoyed with them and I always switch them to 0 or .5. You can do that in Settings-Developers options
Task Killers: task killers, clean maters and similar software is a big NO. You dont need it. It does more damage then good.​
Bloatware
Yes, bloatware. There is huge amount of bloatware on our phones and we really do not need it. So, what to do? Freeze that bloatware.
You can find list of apps HERE.​
ROMS and kernels
Custom ROMs and kernels will give you in most cases better battery life then stock firmware. Plus there is huge amount of options to play with. You can read more in posts bellow.​
Summary:
If you change some of those thing you will see the effect.
You can always use apps like Greenify or Tasker and play with their options.​
How to follow your battery life
GSam Battery Monitor
This one of the most useful apps to track your battery. On Lollipop (even on Kitkat) it will not give you much useful info without root.
If you are using it without root everytime you reboot the phone statistic would be reset also. If you have root it will give you access to wakelocks and some other stuff, plus stats would not get reseted.
Play store link​
Wakelock detector
Wakelocks, one of the painful things on phone. If you see your battery is draining faster in idle then you got problem with wakelocks. This is useful app because it shows wakelocks on very simple setup and you can discover which app is causing which wakelock.
Play Store link​
Disable service
If you are using Wakelock detector you need this app also. With this app you can freeze every single process that app can launch. It will provide detail look on all processes from apps. With this app I have reduced wakelocks to 1%.
Play Store link​

ROMS
Discussion about ROMs never looked nice. It always gets to what you personally like. Some ROMs will be easier on battery, some will be rough. You will never know before you try them.​
Kernels
Kernels are similar to ROMS but you can play with them. Currently there is not much kernels available but you can play even with stock one.
I recommend to use Trickster MOD Kernel Settings app to play with kernel settings.​
Undervoting
Undervolting is the thing when you control how much power each CPU frequency can have. Trickster MOD app gives really nice view on them. You can undervolt every frequency by itself or all in one.
My personal recommendation is to undervolt them at once. I always use -50 value. Found it stable.
Of course, you can always play with different values but remember: when you play with this do not click on option "Set on Boot" or you will end in bootloop if you click it. Click that option when you find out that values are safe for using and stable.​
Underclocking
Underclocking is changing your CPU frequency. Rough truth is that we dont need our CPU to run on 2,7 GHz in normal use. Only gamers will need that probably but since this is not thread were we are aiming gamers we dont need that high frequency.
Me personally, I use always 1,7 GHz or 1,9 GHz. To my daily usage (most common like everyone else but without games) this is more then enough. Everything is still smooth and runs fast.​
Governors
A CPU governor in Android controls how the CPU raises and lowers its frequency in response to the demands the user is placing on their device. Governors are especially important in smartphones and tablets because they have a large impact on the apparent fluidity of the interface and the battery life of the device over a charge.
You can find explanation hidden here.
Many users have wrote about governors and they are practically the same on most of the phones so I will copy list from droidphile.
On his topic you have more details about governors.
Link to original topic: http://forum.xda-developers.com/galaxy-s2/general/ref-kernel-governors-modules-o-t1369817
I) MANUAL:
These are the 19 governors we're talking about.
1) Ondemand
2) Ondemandx
3) Conservative
4) Interactive
5) Interactivex
6) Lulzactive
7) Lulzactiveq
8) Smartass
9) SmartassV2
10) Intellidemand
11) Lazy
12) Lagfree
13) Lionheart
14) LionheartX
15) Brazilianwax
16) SavagedZen
17) Userspacce
18) Powersave
19) Performance
1) Ondemand:
Default governor in almost all stock kernels. One main goal of the ondemand governor is to switch to max frequency as soon as there is a CPU activity detected to ensure the responsiveness of the system. (You can change this behavior using smooth scaling parameters, refer Siyah tweaks at the end of 3rd post.) Effectively, it uses the CPU busy time as the answer to "how critical is performance right now" question. So Ondemand jumps to maximum frequency when CPU is busy and decreases the frequency gradually when CPU is less loaded/apporaching idle. Even though many of us consider this a reliable governor, it falls short on battery saving and performance on default settings. One potential reason for ondemand governor being not very power efficient is that the governor decide the next target frequency by instant requirement during sampling interval. The instant requirement can response quickly to workload change, but it does not usually reflect workload real CPU usage requirement in a small longer time and it possibly causes frequently change between highest and lowest frequency.
2) Ondemandx:
Basically an ondemand with suspend/wake profiles. This governor is supposed to be a battery friendly ondemand. When screen is off, max frequency is capped at 500 mhz. Even though ondemand is the default governor in many kernel and is considered safe/stable, the support for ondemand/ondemandX depends on CPU capability to do fast frequency switching which are very low latency frequency transitions. I have read somewhere that the performance of ondemand/ondemandx were significantly varying for different i/o schedulers. This is not true for most of the other governors. I personally feel ondemand/ondemandx goes best with SIO I/O scheduler.
3) Conservative:
A slower Ondemand which scales up slowly to save battery. The conservative governor is based on the ondemand governor. It functions like the Ondemand governor by dynamically adjusting frequencies based on processor utilization. However, the conservative governor increases and decreases CPU speed more gradually. Simply put, this governor increases the frequency step by step on CPU load and jumps to lowest frequency on CPU idle. Conservative governor aims to dynamically adjust the CPU frequency to current utilization, without jumping to max frequency. The sampling_down_factor value acts as a negative multiplier of sampling_rate to reduce the frequency that the scheduler samples the CPU utilization. For example, if sampling_rate equal to 20,000 and sampling_down_factor is 2, the governor samples the CPU utilization every 40,000 microseconds.
4) Interactive:
Can be considered a faster ondemand. So more snappier, less battery. Interactive is designed for latency-sensitive, interactive workloads. Instead of sampling at every interval like ondemand, it determines how to scale up when CPU comes out of idle. The governor has the following advantages: 1) More consistent ramping, because existing governors do their CPU load sampling in a workqueue context, but interactive governor does this in a timer context, which gives more consistent CPU load sampling. 2) Higher priority for CPU frequency increase, thus giving the remaining tasks the CPU performance benefit, unlike existing governors which schedule ramp-up work to occur after your performance starved tasks have completed. Interactive It's an intelligent Ondemand because of stability optimizations. Why??
Sampling the CPU load every X ms (like Ondemand) can lead to under-powering the CPU for X ms, leading to dropped frames, stuttering UI, etc. Instead of sampling the CPU at a specified rate, the interactive governor will check whether to scale the CPU frequency up soon after coming out of idle. When the CPU comes out of idle, a timer is configured to fire within 1-2 ticks. If the CPU is very busy between exiting idle and when the timer fires, then we assume the CPU is underpowered and ramp to max frequency.
5) Interactivex:
This is an Interactive governor with a wake profile. More battery friendly than interactive.
6) Lulzactive:
This new find from Tegrak is based on Interactive & Smartass governors and is one of the favorites.
Old Version: When workload is greater than or equal to 60%, the governor scales up CPU to next higher step. When workload is less than 60%, governor scales down CPU to next lower step. When screen is off, frequency is locked to global scaling minimum frequency.
New Version: Three more user configurable parameters: inc_cpu_load, pump_up_step, pump_down_step. Unlike older version, this one gives more control for the user. We can set the threshold at which governor decides to scale up/down. We can also set number of frequency steps to be skipped while polling up and down.
When workload greater than or equal to inc_cpu_load, governor scales CPU pump_up_step steps up. When workload is less than inc_cpu_load, governor scales CPU down pump_down_step steps down.
Example:
Consider
inc_cpu_load=70
pump_up_step=2
pump_down_step=1
If current frequency=200, Every up_sampling_time Us if cpu load >= 70%, cpu is scaled up 2 steps - to 800.
If current frequency =1200, Every down_sampling_time Us if cpu load < 70%, cpu is scaled down 1 step - to 1000.
7) Lulzactiveq:
Lulzactiveq is a modified lulzactive governor authored by XDA member robertobsc and is adapted in Siyah kernel for GS2 and GS3. Lulzactiveq aims to optimize the second version of luzactive from Tegrak by a) providing an extra parameter (dec_cpu_load) to make scaling down more sensible, and b) incorporating hotplug logic to the governor. Luzactiveq is the first ever interactive based governor with hotplugging logic inbuilt (atleast the first of its kind for the exynos platform). When CPU comes out of idle loop and it's time to make a scaling decision, if load >= inc_cpu_load CPU is scaled up (like original luzactiveq) and if load <dec_cpu_load, CPU is scaled down. This possibly eliminates the strict single cut-off frequency for luzactiveq to make CPU scaling decisions. Also, stand hotplug logic runs as a separate thread with the governor so that external hotplugging logic is not required to control hotplug in and out (turn On and Off) CPU cores in multi core devices like GS2 or GS3. Only a multi core aware governor makes real sense on muti-core devices. Lulzactiveq and pegasusq aims to do that.
8) Smartass:
Result of Erasmux rewriting the complete code of interactive governor. Main goal is to optimize battery life without comprising performance. Still, not as battery friendly as smartassV2 since screen-on minimum frequency is greater than frequencies used during screen-off. Smartass would jump up to highest frequency too often as well.
9) SmartassV2:
Version 2 of the original smartass governor from Erasmux. Another favorite for many a people. The governor aim for an "ideal frequency", and ramp up more aggressively towards this freq and less aggressive after. It uses different ideal frequencies for screen on and screen off, namely awake_ideal_freq and sleep_ideal_freq. This governor scales down CPU very fast (to hit sleep_ideal_freq soon) while screen is off and scales up rapidly to awake_ideal_freq (500 mhz for GS2 by default) when screen is on. There's no upper limit for frequency while screen is off (unlike Smartass). So the entire frequency range is available for the governor to use during screen-on and screen-off state. The motto of this governor is a balance between performance and battery.
10) Intellidemand:
Intellidemand aka Intelligent Ondemand from Faux is yet another governor that's based on ondemand. Unlike what some users believe, this governor is not the replacement for OC Daemon (Having different governors for sleep and awake). The original intellidemand behaves differently according to GPU usage. When GPU is really busy (gaming, maps, benchmarking, etc) intellidemand behaves like ondemand. When GPU is 'idling' (or moderately busy), intellidemand limits max frequency to a step depending on frequencies available in your device/kernel for saving battery. This is called browsing mode. We can see some 'traces' of interactive governor here. Frequency scale-up decision is made based on idling time of CPU. Lower idling time (<20%) causes CPU to scale-up from current frequency. Frequency scale-down happens at steps=5% of max frequency. (This parameter is tunable only in conservative, among the popular governors )
To sum up, this is an intelligent ondemand that enters browsing mode to limit max frequency when GPU is idling, and (exits browsing mode) behaves like ondemand when GPU is busy; to deliver performance for gaming and such. Intellidemand does not jump to highest frequency when screen is off.
11) Lazy:
This governor from Ezekeel is basically an ondemand with an additional parameter min_time_state to specify the minimum time CPU stays on a frequency before scaling up/down. The Idea here is to eliminate any instabilities caused by fast frequency switching by ondemand. Lazy governor polls more often than ondemand, but changes frequency only after completing min_time_state on a step overriding sampling interval. Lazy also has a screenoff_maxfreq parameter which when enabled will cause the governor to always select the maximum frequency while the screen is off.
12) Lagfree:
Lagfree is similar to ondemand. Main difference is it's optimization to become more battery friendly. Frequency is gracefully decreased and increased, unlike ondemand which jumps to 100% too often. Lagfree does not skip any frequency step while scaling up or down. Remember that if there's a requirement for sudden burst of power, lagfree can not satisfy that since it has to raise cpu through each higher frequency step from current. Some users report that video playback using lagfree stutters a little.
13) Lionheart:
Lionheart is a conservative-based governor which is based on samsung's update3 source. Tweaks comes from 1) Knzo 2) Morfic. The original idea comes from Netarchy. See here. The tunables (such as the thresholds and sampling rate) were changed so the governor behaves more like the performance one, at the cost of battery as the scaling is very aggressive.
To 'experience' Lionheart using conservative, try these tweaks:
sampling_rate:10000 or 20000 or 50000, whichever you feel is safer. (transition latency of the CPU is something below 10ms/10,000uS hence using 10,000 might not be safe).
up_threshold:60
down_threshold:30
freq_step:5
Lionheart goes well with deadline i/o scheduler. When it comes to smoothness (not considering battery drain), a tuned conservative delivers more as compared to a tuned ondemand.
14) LionheartX
LionheartX is based on Lionheart but has a few changes on the tunables and features a suspend profile based on Smartass governor.
15) Brazilianwax:
Similar to smartassV2. More aggressive ramping, so more performance, less battery.
16) SavagedZen:
Another smartassV2 based governor. Achieves good balance between performance & battery as compared to brazilianwax.
17) Userspace:
Instead of automatically determining frequencies, lets user set frequencies.
18) Powersave:
Locks max frequency to min frequency. Can not be used as a screen-on or even screen-off (if scaling min frequency is too low).
19) Performance:
Sets min frequency as max frequency. Use this while benchmarking!​
Schedulers
Everything has been said about them so I will use droidphile explanations.
Link to original topic: http://forum.xda-developers.com/galaxy-s2/general/ref-kernel-governors-modules-o-t1369817
Q. "What purposes does an i/o scheduler serve?"
A.
Minimize hard disk seek latency.
Prioritize I/O requests from processes.
Allocate disk bandwidth for running processes.
Guarantee that certain requests will be served before a deadline.
So in the simplest of simplest form: Kernel controls the disk access using I/O Scheduler.
Q. "What goals every I/O scheduler tries to balance?"
A.
Fairness (let every process have its share of the access to disk)
Performance (try to serve requests close to current disk head position first, because seeking there is fastest)
Real-time (guarantee that a request is serviced in a given time)
Q. "Description, advantages, disadvantages of each I/O Scheduler?"
A.
1) Noop
Inserts all the incoming I/O requests to a First In First Out queue and implements request merging. Best used with storage devices that does not depend on mechanical movement to access data (yes, like our flash drives). Advantage here is that flash drives does not require reordering of multiple I/O requests unlike in normal hard drives.
Advantages:
Serves I/O requests with least number of cpu cycles. (Battery friendly?)
Best for flash drives since there is no seeking penalty.
Good throughput on db systems.
Disadvantages:
Reduction in number of cpu cycles used is proportional to drop in performance.
2) Deadline
Goal is to minimize I/O latency or starvation of a request. The same is achieved by round robin policy to be fair among multiple I/O requests. Five queues are aggressively used to reorder incoming requests.
Advantages:
Nearly a real time scheduler.
Excels in reducing latency of any given single I/O.
Best scheduler for database access and queries.
Bandwidth requirement of a process - what percentage of CPU it needs, is easily calculated.
Like noop, a good scheduler for solid state/flash drives.
Disadvantages:
When system is overloaded, set of processes that may miss deadline is largely unpredictable.
3) CFQ
Completely Fair Queuing scheduler maintains a scalable per-process I/O queue and attempts to distribute the available I/O bandwidth equally among all I/O requests. Each per-process queue contains synchronous requests from processes. Time slice allocated for each queue depends on the priority of the 'parent' process. V2 of CFQ has some fixes which solves process' i/o starvation and some small backward seeks in the hope of improving responsiveness.
Advantages:
Considered to deliver a balanced i/o performance.
Easiest to tune.
Excels on multiprocessor systems.
Best database system performance after deadline.
Disadvantages:
Some users report media scanning takes longest to complete using CFQ. This could be because of the property that since the bandwidth is equally distributed to all i/o operations during boot-up, media scanning is not given any special priority.
Jitter (worst-case-delay) exhibited can sometimes be high, because of the number of tasks competing for the disk.
4) BFQ
Instead of time slices allocation by CFQ, BFQ assigns budgets. Disk is granted to an active process until it's budget (number of sectors) expires. BFQ assigns high budgets to non-read tasks. Budget assigned to a process varies over time as a function of it's behavior.
Advantages:
Believed to be very good for usb data transfer rate.
Believed to be the best scheduler for HD video recording and video streaming. (because of less jitter as compared to CFQ and others)
Considered an accurate i/o scheduler.
Achieves about 30% more throughput than CFQ on most workloads.
Disadvantages:
Not the best scheduler for benchmarking.
Higher budget assigned to a process can affect interactivity and increased latency.
5) SIO
Simple I/O scheduler aims to keep minimum overhead to achieve low latency to serve I/O requests. No priority quesues concepts, but only basic merging. Sio is a mix between noop & deadline. No reordering or sorting of requests.
Advantages:
Simple, so reliable.
Minimized starvation of requests.
Disadvantages:
Slow random-read speeds on flash drives, compared to other schedulers.
Sequential-read speeds on flash drives also not so good.
6) V(R)
Unlike other schedulers, synchronous and asynchronous requests are not treated separately, instead a deadline is imposed for fairness. The next request to be served is based on it's distance from last request.
Advantages:
May be best for benchmarking because at the peak of it's 'form' VR performs best.
I/O Schedulers
Disadvantages:
Performance fluctuation results in below-average performance at times.
Least reliable/most unstable.
7) Anticipatory
Based on two facts
i) Disk seeks are really slow.
ii) Write operations can happen whenever, but there is always some process waiting for read operation.
So anticipatory prioritize read operations over write. It anticipates synchronous read operations.
Advantages:
Read requests from processes are never starved.
As good as noop for read-performance on flash drives.
Disadvantages:
'Guess works' might not be always reliable.
Reduced write-performance on high performance disks.​

CPU & GPU Governors And I/O Schedulers performance Optimization

Thank to zhanjia & Andrux​
I Search about Governors And I/O Schedulers in Google & XDA
Iam sharing this information to our yu Team members .because the Governors And I/O Schedulers is the main part of the Kernels .
Governors And I/O Schedulers
1.Performance
2.Battery
3.Gaming
4.Laging
5.Multitasking ​
CPU Governors​
What is a CPU governor?​
A CPU governor in Android controls how the CPU raises and lowers its frequency in response to the demands the user is placing on their device. Governors are especially important in smartphones and tablets because they have a large impact on the apparent fluidity of the interface and the battery life of the device over a charge.
NOTE: You cannot change your CPU governor unless your phone is rooted and you have a ROM or app that lets you make a change. Also, different kernels (the intermediary software between your phone's hardware and the operating system) offer different sets of governors.
Available CPU governors:
OnDemand
Conservative
Interactive
Performance
Powersave
Scary
Userspace
Smartass
SmartassV2
Smoothass
Brazilianwax
SavagedZen
Lagfree
MinMax
Interactivex
OnDemand
OnDemand
Available in most kernels, and the default governor in most kernels. When the CPU load reaches a certain point, OnDemand will rapidly scale the CPU up to meet the demand, then gradually scale the CPU down when it isn't needed.
Review
Brief says all. By a simple explantion, OnDemand scales up to the required frequency to undergo the action you are doing and rapidly scales down after use.
Conservative
It is similar to the OnDemand governor, but will scale the CPU up more gradually to better fit demand. Conservative governor provides a less responsive experience than OnDemand, but it does save batter
Review
Conservative is the opposite of Interactive; it will slowly ramp up the frequency, then quickly drops the frequency once the CPU is no longer under a certain usage.
Interactive
Available in latest kernels, it is the default scaling option in some stock kernels. Interactive governor is similar to the OnDemand governor with an even greater focus on responsiveness.
Review
Interactive is the opposite of Conservative; it quickly scales up to the maximum allowed frequency, then slowly drops the frequency once no longer in use.
Performance
Performance governer locks the phone's CPU at maximum frequency. While this may sound like an ugly idea, there is growing evidence to suggest that running a phone at its maximum frequency at all times will allow a faster race-to-idle. Race-to-idle is the process by which a phone completes a given task. After that it returns the CPU to extremely efficient low-power state.
Review
Good at gaming, Really good. Disadvantages are it may damage your phone if too much usage.
Powersave
The opposite of the Performance governor, the Powersave governor locks the CPU frequency at the lowest frequency set by the user.
Review
Set it to your desired minimum frequency and you won't have to look for your charger for once in a while.
Scary
A new governor wrote based on Conservative with some Smartass features, it scales accordingly to Conservative's way. It will start from the bottom. It spends most of its time at lower frequencies. The goal of this is to get the best battery life with decent performance. It will give the same performance as Conservative right now.
Review
Hmm.. Overall I don't see any difference. After I understand its main objective. I was very curious and decided to use it again. Results are the same.. No difference. Report to me if anyone has tested this.
Userspace
Userspace is not a governor pre-set, but instead allows for non-kernel daemons or apps with root permissions to control the frequency. Commonly seen as a redundant and not useful since SetCPU and NoFrills exist.
Review
Highly not recommended for use.
Smartass
It is based on the concept of the Interactive governor.
Smartass is a complete rewrite of the code of Interactive. Performance is on par with the “old” minmax and Smartass is a bit more responsive. Battery life is hard to quantify precisely but it does spend much more time at the lower frequencies.
Review
Smartass is rather the governer that will save your battery and make use of your processor for daily use. Like the brief explantion said " Smartass will spend much more time on lower frequencies." So logically you don't need for sleep profiles anymore.
SmartassV2
Theoretically a merge of the best properties of Interactive and OnDemand; automatically reduces the maximum CPU frequency when phone is idle or asleep, and attempts to balance performance with efficiency by focusing on an "ideal" frequency.
Review
This is a much favourite to everybody. I believe almost everyone here is using SmartassV2. Yes, it is better than Smartass because of its speed no scaling frequencies from min to max at a short period of time.
Smoothass
A much more aggressive version of Smartass that is very quick to ramp up and down, and keeps the idle/asleep maximum frequency even lower.
Review
In my personal experience, this is really useful for daily use. And yes, I'm using it all the time. It may decrease your battery life. I saw it OC itself to 1.4 gHz when I set it to 1.2. Good use. Recommended.
Brazilianwax
Similar to SmartassV2. More aggressive scaling, so more performance, but less battery.
Review
Based on SmartassV2. But its advantage is a much more performance wise governor.
SavagedZen
Another SmartassV2 based governor. Achieves good balance between performance & battery as compared to Brazilianwax.
Review
Not much difference compared to SmartassV2. But it is a optimized version of it.
Lagfree
Again, similar to Smartass but based on Conservative rather than Interactive, instantly jumps to a certain CPU frequency after the device wakes, then operates similar to Conservative. However, it has been noted as being very slow when down-scaling, taking up to a second to switch frequencies.
Review
Used it before. Like the name of the governor, I didn't experience any lag whatsoever. Another governor based on performance, but not battery efficient.
MinMax
MinMax is just a normal governor. No scaling intermediate frequency scaling is used.
Review
Well.. it's too normal that I can't really say anything about it..
Interactivex
InteractiveX governor is based heavily on the Interactive governor, enhanced with tuned timer parameters to optimize the balance of battery vs performance. InteractiveX governor's defining feature, however, is that it locks the CPU frequency to the user's lowest defined speed when the screen is off.
Review
A better understanding from the brief to you users, this is an Interactive governor with a wake profile. More battery friendly than Interactive.
GPU Governors
Ondemand
Much like the CPU governor, Ondemand will ramp up the frequency when a load is detected. A good balance between performance and battery savings.*
MSM-Adreno
The default GPU governor used by qualcomm for their adreno GPUs. It is more performance orientated than ondemand therefore it gives better performance in games but less battery life.*
Performance
As the name suggests, this keeps your GPU running at the max frequency. This is a governor if you want the best possible experience in games but you don't care about your battery life.*
Powersave
Like the CPU governor, this keeps your GPU running at the lowest possible frequency. Best battery life
I/O Schedulers
What is an I/O Scheduler:
*Input/output (I/O) scheduling is a term used to describe the method computer operating systems decide the order that block I/O operations will be submitted to storage volumes. I/O Scheduling is sometimes called 'disk scheduling'.
I/O schedulers can have many purposes depending on the goal of the I/O scheduler, some common goals
To minimise time wasted by hard disk seeks.
To prioritise a certain processes' I/O requests.
To give a share of the disk bandwidth to each running process.
To guarantee that certain requests will be issued before a particular deadline.​
Available*I/O schedulers
CFQ *
Deadline *
VR *
Noop*
Anticipatory
BFQ
FIOPS
SIO (Simple)
Row
ZEN
Sioplus
FIFO*
Tripndroid
Anticipatory:*
Two important things here are indicative of that event:*
- Looking on the flash drive is very slow from boot
- Write operations while at any time are processed, however, be read operations preferred, ie, this scheduler returns the read operations a higher priority than the write operations.*
Benefits:*
- Requests of read accesses are never treated secondarily, that has equally good reading performance on flash drives like noop.
Disadvantages:*
- Requests from process operations are not always available*
- Reduced write performance on high-performance hard drives*
- Not very common in most kernels
CFQ:*
The CFQ - Completely Fair Queuing - similar to the Dead Line maintains a scalable continuous Process-I/O, the available I / O bandwidth is *fairly and evenly shared to all I / O requests to distribute. It creates a statistics between blocks and processes. With these statistics it can "guess" when the next block is requested by what process, each process queue contains requests of synchronous processes, which in turn is dependent upon the priority of the original process. There the V2 version has some fixes, such as I / O request improvements, hunger fixes , and some small search backward integrated to improve responsiveness.This is the default IO scheduler for Samsung smartphones.*
Benefits:*
- Has a well balanced I / O performance
- Excellent on multiprocessor systems*
- Easiest to tune.
- Best performance of the database after the deadline*
- Is the default IO scheduler for most mobile phones today
- Good for multitasking*
Disadvantages:*
- *Some users report media scanning takes longest to complete using CFQ. This could be because of the property that since the bandwidth is equally distributed to all i/o operations during boot-up, media scanning is not given any special priority.*
- Jitter (worst case delay) can sometimes be very high because the number of competing with each other process tasks*
Deadline:*
This scheduler has the goal of reducing I / O wait time of a process of inquiry. This is done using the block numbers of the data on the drive. This also blocks an outlying block numbers are processed, each request receives a maximum delivery time. This is in addition to the Governor BFQ, it is very popular and is in many well known kernels.*
Benefits:*
- It is nearly a real-time scheduler.*
- Excels in reducing latency of any given single I/O*
- Best scheduler for database access and queries.*
- Does quite well in benchmarks, most likely the best
- Like noop, a good scheduler for solid state/flash drives
- Good for light and medium multitasking workloads
Disadvantages:*
- If the phone is overloaded, crashing or unexpected closure of processes can occur*
- Bad battery life if doing a lot of multitasking
ROW:
ROW stands for "READ Over WRITE"which is the main requests dispatch policy of this algorithm. The ROW IO scheduler was developed with the mobile devices needs in mind. In mobile devices we favor user experience upon everything else,thus we want to give READ IO requests as much priority as possible. In mobile devices we won't have as much parallel threads as on desktops. Usually it's a single thread or at most 2 simultaneous working threads for read & write. Favoring READ requests over WRITEs decreases the READ latency greatly.
The main idea of the ROW scheduling policy is: If there are READ requests in pipe - dispatch them but don't starve the WRITE requests too much. Bellow you'll find a small comparison of ROW to existing schedulers. The test that was run for these measurements is parallel read and write.
Benefits:
- Faster UI navigation and better overall phone experience
- Faster boot times and app launch times*
- Possibly better battery life
- Sometimes used by default for custom roms and custom kernels
Disadvantages:
- Slower write speeds
- Some intensive applications like games could slow down your phone
SIO (Simple):*
It aims to achieve with minimal effort at a low latency I / O requests. Not a priority to put in queue, instead simply merge the requests. This scheduler is a mix between the noop and deadline. There is no conversion or sorting of requests.*
Benefits:*
- It is simple and stable.
- Reliable IO scheduler
- Minimized starvation for inquiries
- Good battery life
Disadvantages:*
- Slow random write speeds on flash drives as opposed to other schedulers.
- Sequential read speeds on flash drives, not as good*
Noop:*
The noop scheduler is the simplest of them. It is best suited for storage devices that are not subject to mechanical movements, such as our flash drives in our phones use to access the data. The advantage is that flash drives do not require rearrangement of the I / O requests, unlike normal hard drives. the data that come first are written first. It's basically not a real scheduler, as it leaves the scheduling of the hardware.*
Benefits:*
- Serves I/O requests with least number of cpu cycles.
- Is suitable for flash drives because there is no search errors*
- Good data throughput on db systems
Disadvantages:*
- Reducing the number of CPU cycles corresponds to a simultaneous decline in performance*
- Not very good at multitasking
VR:*
Unlike other scheduling software, synchronous and asynchronous requests are not handled separately, but it will impose a fair and balanced within this deadline requests, that the next request to be served is a function of distance from the last request. It is a very good scheduler with elements of the deadline scheduler. It is the best for MTD Android devices. Vr can make the most of the benchmark points, but it is also an unstable scheduler. *Sometimes the scores fluctuate below the average, sometimes it fluctuates above the average.*
Benefits:
- Generally excels in random writes.*
Disadvantages:*
- Performance variability can lead to different results (Only performs well sometimes)
- Very often unstable and unreliable
BFQ:*
Instead requests divided into time segments as the CFQ has, on the BFQ budget. The flash drive will be granted an active process until it has exhausted its budget (number of sectors on the flash drive). The awards BFQ high budget does not read tasks. BFQ has received many updates to the scheduler and the performance is consistently improving.*
Benefits:*
- Has a very good USB data transfer rate.*
- The best scheduler for playback of HD video recording and video streaming (due to less jitter than CFQ Scheduler, and others)*
- Regarded as a very precise working Scheduler*
- Delivers 30% more throughput than CFQ
- Being constantly updated
- Good for multitasking*
Disadvantages:*
- Not the best scheduler for benchmarks*
- Higher budgets that were allocated to a process that can affect the interactivity and bring with it increased latency.*
- Slower UI navigation
- Slower boot times
ZEN:
Based on the VR Scheduler. It's an FCFS (First come, first serve) based algorithm. It's not strictly FIFO. It does not do any sorting. It uses deadlines for fairness, and treats synchronous requests with priority over asynchronous ons. Other than that, pretty much the same as no-op.
Benefits:
- Well rounded IO Scheduler
- Very efficient IO Scheduler
- More stable than VR, mainly because it doesn't really behave like VR.*
Disadvantages:
- Not found in all kernels
Sioplus:
Based on the original Sio scheduler with improvements. Functionality for specifying the starvation of async reads against sync reads; starved write requests counter only counts when there actually are write requests in the queue; fixed a bug).*
Benefits:
- Better read and write speeds than previous SIO scheduler
- Good battery life*
Disadvantages:
- The same as SIO scheduler
- Not found in all kernels
FIOPS:*
This new I/O scheduler is designed around the following assumptions about Flash-based storage devices: no I/O seek time, read and write I/O cost is usually different from rotating media, time to make a request depends upon the request size, and high through-put and higher IOPS with low-latency.
Benefits:
- Achieves high read and write speeds in benchmarks
- Good battery life
Disadvantages:
- Not very common in most kernels
FIFO (First in First Out):
A relatively simple io schedulers that does what has been described. It is also known as FCFS (First come first serve) but this really isn't true. It does basic sorting; sorting the processes according to the appropriate order and nothing else. In other words, it is quite similar to noop.*
Benefits:
- Serves I/O requests with least number of cpu cycles.
- Is suitable for flash drives because there is no search errors
- Good data throughput on db systems
Disadvantages:
- Reducing the number of CPU cycles corresponds to a simultaneous decline in performance*
- Not very good at multitasking
Tripndroid
A new I/O scheduler based on noop, deadline and vr and meant to have minimal overhead. Made by TripNRaVeR
Recommended IO schedulers:
For everyday usage:
- SIO (My personal favourite)
- NOOP
- CFQ (Third choice)
- Deadline (Forth choice)
- ROW (My second choice)
- ZEN
For battery life:
- SIO (First choice)
- FIOPS*
- NOOP (Second choice)
- ROW (Third choice)
- FIFO
For gaming:*
- Deadline (First choice)
- CFQ (Second choice)*
- ROW (Third choice)
For performance(Benchmarking):
- VR
- SIO (Third Choice)
- Deadline (Second choice)
- FIOPS (First choice)*
For multitasking:*
- BFQ (Third choice)
- Deadline (Second choice)
- CFQ (First choice)
IO Scheduler Comparison
Overall performance:
Best<------------------------------------------------------------------------->Worst
FIOPS> Noop > ZEN >SIOplus > SIO > ROW > Tripndroid > VR > Deadline > BFQ > CFQ
Multitasking performance:
Less Apps<------------------------------------------------------------>Many Apps
Noop < FIOPS < SIO < *SIOplus < ROW < Tripndroid < ZEN < Deadline < VR < *CFQ < BFQ
Battery life:
Best<-------------------------------------------------------------------------> Worst
Noop > FIOPS > SIOplus > SIO > ROW> *ZEN > Tripndroid > Deadline > VR > CFQ > BFQ​

ela1103 said:
Thank to zhanjia & Andrux​
I Search about Governors And I/O Schedulers in Google & XDA
Iam sharing this information to our yu Team members .because the Governors And I/O Schedulers is the main part of the Kernels .
Governors And I/O Schedulers
1.Performance
2.Battery
3.Gaming
4.Laging
5.Multitasking ​
​
Click to expand...
Click to collapse
Thanks, very informative!
schubeir

Thanks man for the info, i knew few of them and now all:good::good::good:

No credits??? I'm sure those descriptions for I/O schedulers came from me

Thanks been looking for something like this
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