Legacy Documentation: Version 4.5
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Measuring Performance with the Built-in Profiler

Unity iOS and Android contain a built in profiler. This is included in all versions of the add-ons, and is not a Pro feature. (Pro add-ons do contain a more advanced profiler, however.) The built-in profiler emits console messages from the game running on device. These messages are written every 30 seconds and will provide insight into how the game is running. Understanding what these messages mean is not always easy, but as a minimum, you should quickly be able to determine if your game is CPU or GPU bound, and if CPU bound whether it’s script code, or perhaps Mono garbage collection that is slowing you down. See later in this page to learn how to configure the built-in profiler.

What the Profiler Tells You

Here’s an example of the built-in profiler’s output.

iPhone/iPad Unity internal profiler stats:
cpu-player> min: 9.8 max: 24.0 avg: 16.3
cpu-ogles-drv> min: 1.8 max: 8.2 avg: 4.3
cpu-waits-gpu> min: 0.8 max: 1.2 avg: 0.9
cpu-present> min: 1.2 max: 3.9 avg: 1.6
frametime> min: 31.9 max: 37.8 avg: 34.1
draw-call #> min: 4 max: 9 avg: 6 | batched: 10
tris #> min: 3590 max: 4561 avg: 3871 | batched: 3572
verts #> min: 1940 max: 2487 avg: 2104 | batched: 1900
player-detail> physx: 1.2 animation: 1.2 culling: 0.5 skinning: 0.0 batching: 0.2 render: 12.0 fixed-update-count: 1 .. 2
mono-scripts> update: 0.5 fixedUpdate: 0.0 coroutines: 0.0 
mono-memory> used heap: 233472 allocated heap: 548864 max number of collections: 1 collection total duration: 5.7

All times are measured in milliseconds per frame. You can see the minimum, maximum and average times over the last thirty frames.

General CPU Activity

cpu-player Displays the time your game spends executing code inside the Unity engine and executing scripts on the CPU.
cpu-ogles-drv Displays the time spent executing OpenGL ES driver code on the CPU. Many factors like the number of draw calls, number of internal rendering state changes, the rendering pipeline setup and even the number of processed vertices can have an effect on the driver stats.
cpu-waits-gpu Displays the time the CPU is idle while waiting for the GPU to finish rendering. If this number exceeds 2–3 milliseconds then your application is most probably fillrate/GPU processing bound. If this value is too small then the profile skips displaying the value.
msaa-resolve The time taken to apply anti-aliasiing.
cpu-present The amount of time spent executing the presentRenderbuffer command in OpenGL ES.
frametime Represents the overall time of a game frame. Note that iOS hardware is always locked at a 60Hz refresh rate, so you will always get multiples times of 16.7ms (1000ms/60Hz = 16.7ms).

Rendering Statistics

draw-call # The number of draw calls per frame. Keep it as low as possible.
tris # Total number of triangles sent for rendering.
verts # Total number of vertices sent for rendering. You should keep this number below 10000 if you use only static geometry but if you have lots of skinned geometry then you should keep it much lower.
batched Number of draw-calls, triangles and vertices which were automatically batched by the engine. Comparing these numbers with draw-call and triangle totals will give you an idea how well is your scene prepared for batching. Share as many materials as possible among your objects to improve batching.

Detailed Unity Player Statistics

The player-detail section provides a detailed breakdown of what is happening inside the engine:-

physx Time spent on physics.
animation Time spent animating bones.
culling Time spent culling objects outside the camera frustum.
skinning Time spent applying animations to skinned meshes.
batching Time spent batching geometry. Batching dynamic geometry is considerably more expensive than batching static geometry.
render Time spent rendering visible objects.
fixed-update-count Minimum and maximum number of FixedUpdates executed during this frame. Too many FixedUpdates will deteriorate performance considerably.

Detailed Scripts Statistics

The mono-scripts section provides a detailed breakdown of the time spent executing code in the Mono runtime:

update Total time spent executing all Update() functions in scripts.
fixedUpdate Total time spent executing all FixedUpdate() functions in scripts.
coroutines Time spent inside script coroutines.

Detailed Statistics on Memory Allocated by Scripts

The mono-memory section gives you an idea of how memory is being managed by the Mono garbage collector:

allocated heap Total amount of memory available for allocations. A garbage collection will be triggered if there is not enough memory left in the heap for a given allocation. If there is still not enough free memory even after the collection then the allocated heap will grow in size.
used heap The portion of the allocated heap which is currently used up by objects. Every time you create a new class instance (not a struct) this number will grow until the next garbage collection.
max number of collections Number of garbage collection passes during the last 30 frames.
collection total duration Total time (in milliseconds) of all garbage collection passes that have happened during the last 30 frames.

Configuration

On iOS, it’s disabled by default so to enable it, you need to open the Unity-generated XCode project, select the iPhone_Profiler.h file and change the line

 #define ENABLE_INTERNAL_PROFILER 0

to

 #define ENABLE_INTERNAL_PROFILER 1

Select View > Debug Area > Activate Console in the XCode menu to display the output console (GDB) and then run your project. Unity will output statistics to the console window every thirty frames.

On Android, it is enabled by default. Just make sure Development Build is checked in the player settings when building, and the statistics should show up in logcat when run on the device. To view logcat, you need <span class="doc-prop">adb</span> or the Android Debug Bridge. Once you have that, simply run the shell command <span class="doc-prop">adb logcat</span>.

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iOS Specific Optimizations
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Optimizing the Size of the Built iOS Player