Struct MLCGroupNormalizationLayer

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#[repr(C)]
pub struct MLCGroupNormalizationLayer { /* private fields */ }

👎Deprecated

Available on crate features MLCGroupNormalizationLayer and MLCLayer only.

Expand description

A group normalizaion layer. For more information, refer to https://pytorch.org/docs/stable/nn.html#groupnorm

Implementations§

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impl MLCGroupNormalizationLayer

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pub unsafe fn featureChannelCount(&self) -> NSUInteger

👎Deprecated

The number of feature channels

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pub unsafe fn groupCount(&self) -> NSUInteger

👎Deprecated

The number of groups to separate the channels into

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pub unsafe fn beta(&self) -> Option<Retained<MLCTensor>>

👎Deprecated

Available on crate feature MLCTensor only.

The beta tensor

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pub unsafe fn gamma(&self) -> Option<Retained<MLCTensor>>

👎Deprecated

Available on crate feature MLCTensor only.

The gamma tensor

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pub unsafe fn betaParameter(&self) -> Option<Retained<MLCTensorParameter>>

👎Deprecated

Available on crate feature MLCTensorParameter only.

The beta tensor parameter used for optimizer update

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pub unsafe fn gammaParameter(&self) -> Option<Retained<MLCTensorParameter>>

👎Deprecated

Available on crate feature MLCTensorParameter only.

The gamma tensor parameter used for optimizer update

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pub unsafe fn varianceEpsilon(&self) -> c_float

👎Deprecated

A value used for numerical stability

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pub unsafe fn layerWithFeatureChannelCount_groupCount_beta_gamma_varianceEpsilon( feature_channel_count: NSUInteger, group_count: NSUInteger, beta: Option<&MLCTensor>, gamma: Option<&MLCTensor>, variance_epsilon: c_float, ) -> Option<Retained<Self>>

👎Deprecated

Available on crate feature MLCTensor only.

Create a group normalization layer

Parameter featureChannelCount: The number of feature channels

Parameter beta: Training parameter

Parameter gamma: Training parameter

Parameter groupCount: The number of groups to divide the feature channels into

Parameter varianceEpsilon: A small numerical value added to variance for stability

Returns: A new group normalization layer.

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impl MLCGroupNormalizationLayer

Methods declared on superclass MLCLayer.

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pub unsafe fn new() -> Retained<Self>

👎Deprecated

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pub unsafe fn init(this: Allocated<Self>) -> Retained<Self>

👎Deprecated

Methods from Deref<Target = MLCLayer>§

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pub unsafe fn layerID(&self) -> NSUInteger

👎Deprecated

The layer ID

A unique number to identify each layer. Assigned when the layer is created.

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pub unsafe fn label(&self) -> Retained<NSString>

👎Deprecated

A string to help identify this object.

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pub unsafe fn setLabel(&self, label: &NSString)

👎Deprecated

Setter for label.

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pub unsafe fn isDebuggingEnabled(&self) -> bool

👎Deprecated

A flag to identify if we want to debug this layer when executing a graph that includes this layer

If this is set, we will make sure that the result tensor and gradient tensors are available for reading on CPU The default is NO. If isDebuggingEnabled is set to YES, make sure to set options to enable debugging when compiling the graph. Otherwise this property may be ignored.

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pub unsafe fn setIsDebuggingEnabled(&self, is_debugging_enabled: bool)

👎Deprecated

Setter for isDebuggingEnabled.

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pub unsafe fn deviceType(&self) -> MLCDeviceType

Available on crate feature MLCTypes only.

The device type where this layer will be executed

Typically the MLCDevice passed to compileWithOptions will be the device used to execute layers in the graph. If MLCDeviceTypeANE is selected, it is possible that some of the layers of the graph may not be executed on the ANE but instead on the CPU or GPU. This property can be used to determine which device type the layer will be executed on.

Methods from Deref<Target = NSObject>§

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pub fn doesNotRecognizeSelector(&self, sel: Sel) -> !

Handle messages the object doesn’t recognize.

See Apple’s documentation for details.

Methods from Deref<Target = AnyObject>§

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pub fn class(&self) -> &'static AnyClass

Dynamically find the class of this object.

§Panics

May panic if the object is invalid (which may be the case for objects returned from unavailable init/new methods).

§Example

Check that an instance of NSObject has the precise class NSObject.

use objc2::ClassType;
use objc2::runtime::NSObject;

let obj = NSObject::new();
assert_eq!(obj.class(), NSObject::class());

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pub unsafe fn get_ivar<T>(&self, name: &str) -> &T
where T: Encode,

👎Deprecated: this is difficult to use correctly, use Ivar::load instead.

Use Ivar::load instead.

§Safety

The object must have an instance variable with the given name, and it must be of type T.

See Ivar::load_ptr for details surrounding this.

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pub fn downcast_ref<T>(&self) -> Option<&T>
where T: DowncastTarget,

Attempt to downcast the object to a class of type T.

This is the reference-variant. Use Retained::downcast if you want to convert a retained object to another type.

§Mutable classes

Some classes have immutable and mutable variants, such as NSString and NSMutableString.

When some Objective-C API signature says it gives you an immutable class, it generally expects you to not mutate that, even though it may technically be mutable “under the hood”.

So using this method to convert a NSString to a NSMutableString, while not unsound, is generally frowned upon unless you created the string yourself, or the API explicitly documents the string to be mutable.

See Apple’s documentation on mutability and on isKindOfClass: for more details.

§Generic classes

Objective-C generics are called “lightweight generics”, and that’s because they aren’t exposed in the runtime. This makes it impossible to safely downcast to generic collections, so this is disallowed by this method.

You can, however, safely downcast to generic collections where all the type-parameters are AnyObject.

§Panics

This works internally by calling isKindOfClass:. That means that the object must have the instance method of that name, and an exception will be thrown (if CoreFoundation is linked) or the process will abort if that is not the case. In the vast majority of cases, you don’t need to worry about this, since both root objects NSObject and NSProxy implement this method.

§Examples

Cast an NSString back and forth from NSObject.

use objc2::rc::Retained;
use objc2_foundation::{NSObject, NSString};

let obj: Retained<NSObject> = NSString::new().into_super();
let string = obj.downcast_ref::<NSString>().unwrap();
// Or with `downcast`, if we do not need the object afterwards
let string = obj.downcast::<NSString>().unwrap();

Try (and fail) to cast an NSObject to an NSString.

use objc2_foundation::{NSObject, NSString};

let obj = NSObject::new();
assert!(obj.downcast_ref::<NSString>().is_none());

Try to cast to an array of strings.

use objc2_foundation::{NSArray, NSObject, NSString};

let arr = NSArray::from_retained_slice(&[NSObject::new()]);
// This is invalid and doesn't type check.
let arr = arr.downcast_ref::<NSArray<NSString>>();

This fails to compile, since it would require enumerating over the array to ensure that each element is of the desired type, which is a performance pitfall.

Downcast when processing each element instead.

use objc2_foundation::{NSArray, NSObject, NSString};

let arr = NSArray::from_retained_slice(&[NSObject::new()]);

for elem in arr {
    if let Some(data) = elem.downcast_ref::<NSString>() {
        // handle `data`
    }
}