Visible to Intel only — GUID: GUID-FAD10424-0359-4F23-8CDC-170659222321
Convolution
Inner Product
Matrix Multiplication
RNN
Batch Normalization
Binary
Concat
Eltwise
General
Execution Arguments
Implementation Details
Implementation Limitations
Performance Tips
Example
Group Normalization
Layer Normalization
Local Response Normalization (LRN)
Pooling
PReLU
Resampling
Shuffle
Softmax
Sum
Reorder
Reduction
Abs
AbsBackward
Add
AvgPool
AvgPoolBackward
BatchNormForwardTraining
BatchNormInference
BatchNormTrainingBackward
BiasAdd
BiasAddBackward
Clamp
ClampBackward
Concat
Convolution
ConvolutionBackwardData
ConvolutionBackwardWeights
ConvTranspose
ConvTransposeBackwardData
ConvTransposeBackwardWeights
Dequantize
Divide
DynamicDequantize
DynamicQuantize
Elu
EluBackward
End
Exp
GroupNorm
GELU
GELUBackward
HardSigmoid
HardSigmoidBackward
HardSwish
HardSwishBackward
Interpolate
InterpolateBackward
LayerNorm
LayerNormBackward
LeakyReLU
Log
LogSoftmax
LogSoftmaxBackward
MatMul
Maximum
MaxPool
MaxPoolBackward
Minimum
Mish
MishBackward
Multiply
Pow
PReLU
PReLUBackward
Quantize
Reciprocal
ReduceL1
ReduceL2
ReduceMax
ReduceMean
ReduceMin
ReduceProd
ReduceSum
ReLU
ReLUBackward
Reorder
Round
Select
Sigmoid
SigmoidBackward
SoftMax
SoftMaxBackward
SoftPlus
SoftPlusBackward
Sqrt
SqrtBackward
Square
SquaredDifference
StaticReshape
StaticTranspose
Subtract
Tanh
TanhBackward
TypeCast
Wildcard
enum dnnl_alg_kind_t
enum dnnl_normalization_flags_t
enum dnnl_primitive_kind_t
enum dnnl_prop_kind_t
enum dnnl_query_t
enum dnnl::normalization_flags
enum dnnl::query
struct dnnl_exec_arg_t
struct dnnl_primitive
struct dnnl_primitive_desc
struct dnnl::primitive
struct dnnl::primitive_desc
struct dnnl::primitive_desc_base
enum dnnl_rnn_direction_t
enum dnnl_rnn_flags_t
enum dnnl::rnn_direction
enum dnnl::rnn_flags
struct dnnl::augru_backward
struct dnnl::augru_forward
struct dnnl::gru_backward
struct dnnl::gru_forward
struct dnnl::lbr_augru_backward
struct dnnl::lbr_augru_forward
struct dnnl::lbr_gru_backward
struct dnnl::lbr_gru_forward
struct dnnl::lstm_backward
struct dnnl::lstm_forward
struct dnnl::rnn_primitive_desc_base
struct dnnl::vanilla_rnn_backward
struct dnnl::vanilla_rnn_forward
Visible to Intel only — GUID: GUID-FAD10424-0359-4F23-8CDC-170659222321
Eltwise
General
Forward
The eltwise primitive applies an operation to every element of the tensor (the variable names follow the standard Naming Conventions):
For notational convenience, in the formulas below we will denote individual element of 
, 
, 
, and 
tensors via s, d, ds, and dd respectively.
The following operations are supported:
Operation |
oneDNN algorithm kind |
Forward formula |
Backward formula (from src) |
Backward formula (from dst) |
|---|---|---|---|---|
abs |
|
|
||
clip |
|
|
||
clip_v2 |
|
|
|
|
elu |
|
|
|
|
exp |
|
|
|
|
gelu_erf |
|
|
||
gelu_tanh |
|
|
||
hardsigmoid |
|
|
||
hardswish |
|
|
||
linear |
|
|
||
log |
|
|
||
logistic |
|
|
|
|
mish |
|
|
||
pow |
|
|
||
relu |
|
|
|
|
round |
|
|||
soft_relu |
|
|
||
sqrt |
|
|
|
|
square |
|
|
||
swish |
|
|
||
tanh |
|
|
|
Note that following equations hold:
Difference Between Forward Training and Forward Inference
There is no difference between the dnnl_forward_training and dnnl_forward_inference propagation kinds.
Backward
The backward propagation computes based on and tensors. However, some operations support a computation using memory produced during the forward propagation. Refer to the table above for a list of operations supporting destination as input memory and the corresponding formulas.
Exceptions
The eltwise primitive with algorithm round does not support backward propagation.
Execution Arguments
When executed, the inputs and outputs should be mapped to an execution argument index as specified by the following table.
Primitive input/output |
Execution argument index |
|---|---|
|
DNNL_ARG_SRC |
|
DNNL_ARG_DST |
|
DNNL_ARG_DIFF_SRC |
|
DNNL_ARG_DIFF_DST |
|
DNNL_ARG_ATTR_MULTIPLE_POST_OP(binary_post_op_position) | DNNL_ARG_SRC_1 |
Implementation Details
General Notes
All eltwise primitives have 3 primitive descriptor creation functions (e.g., dnnl::eltwise_forward::primitive_desc()) which may take both
and 
, just , or none of them.Both forward and backward propagation support in-place operations, meaning that
can be used as input and output for forward propagation, and can be used as input and output for backward propagation. In case of an in-place operation, the original data will be overwritten. Note, however, that some algorithms for backward propagation require original , hence the corresponding forward propagation should not be performed in-place for those algorithms. Algorithms that use for backward propagation can be safely done in-place.For some operations it might be beneficial to compute backward propagation based on
, rather than on 
, for improved performance.For logsigmoid original formula
was replaced by 
for numerical stability.
NOTE:
For operations supporting destination memory as input,
can be used instead of
when backward propagation is computed. This enables several performance optimizations (see the tips below).
Data Type Support
The eltwise primitive supports the following combinations of data types:
Propagation |
Source / Destination |
Intermediate data type |
|---|---|---|
forward / backward |
f32, f64, bf16, f16 |
f32 |
forward |
s32, f64 / s8 / u8 |
f32 |
forward / backward |
f64 |
f64 |
WARNING:
There might be hardware and/or implementation specific restrictions. Check Implementation Limitations section below.
Here the intermediate data type means that the values coming in are first converted to the intermediate data type, then the operation is applied, and finally the result is converted to the output data type.
Data Representation
The eltwise primitive works with arbitrary data tensors. There is no special meaning associated with any logical dimensions.
Post-Ops and Attributes
Implementation Limitations
Refer to Data Types for limitations related to data types support.
GPU
Only tensors of 6 or fewer dimensions are supported.
Performance Tips
For backward propagation, use the same memory format for
, , and (the format of the and are always the same because of the API). Different formats are functionally supported but lead to highly suboptimal performance.Use in-place operations whenever possible (see caveats in General Notes).
As mentioned above for all operations supporting destination memory as input, one can use the
tensor instead of . This enables the following potential optimizations for training:Such operations can be safely done in-place.
Moreover, such operations can be fused as a post-op with the previous operation if that operation does not require its
to compute the backward propagation (e.g., if the convolution operation satisfies these conditions).
Example
Eltwise Primitive Example
This C++ API example demonstrates how to create and execute an Element-wise primitive in forward training propagation mode.