conv2d
fn conv2d(
x: &Tensor<T>,
kernels: &Tensor<T>,
bias: Option<&Tensor<T>>,
steps: [i64; 2],
padding: [i64; 2],
dilation: [i64; 2],
algo: Option<ConvAlgo>
) -> Result<Tensor<T>, TensorError>
Performs a 2D convolution operation with support for stride, padding, dilation.
Parameters:
x: Input tensor with shape [batch_size, height, width, in_channels]
kernels: Convolution kernels tensor with shape [out_channel, kernel_height, kernel_width, in_channels]
bias: Optional bias tensor with shape [out_channels]
steps: Convolution stride as [step_height, step_width]
padding: Padding size as [padding_height, padding_width]
dilation: Kernel dilation factors as [dilation_height, dilation_width]
algo: Optional algorithm to use, None will auto select
Returns:
Tensor with type T
Examples:
use hpt::{
backend::Cuda,
common::TensorInfo,
error::TensorError,
ops::{CudaConv, Random},
Tensor,
};
fn main() -> Result<(), TensorError> {
// [batch_size, height, width, in_channels]
let input = Tensor::<f32, Cuda>::randn([1, 32, 32, 3])?;
// [out_channels, kernel_height, kernel_width, in_channels]
let kernels = Tensor::<f32, Cuda>::randn([16, 3, 3, 3])?;
// Create bias
let bias = Tensor::<f32, Cuda>::randn([16])?;
// Perform convolution with stride 2, no padding, no dilation
let output = input.conv2d(
&kernels,
Some(&bias),
[2, 2], // stride
[0, 0], // padding
[1, 1], // dilation
None, // auto select algo
)?;
println!("Output shape: {:?}", output.shape()); // [batch_size, out_height, out_width, out_channels]
Ok(())
}