Kernel Details - unrolled_loops_convtranspose3d_optimized_edit

import torch
import torch.nn as nn
import torch.nn.functional as F


def module_fn(
    x: torch.Tensor,
    conv_transpose: torch.Tensor,
    conv_transpose_bias: torch.Tensor,
    bias: torch.Tensor,
    scaling_factor: float,
    stride: int,
    padding: int,
) -> torch.Tensor:
    """
    Applies a series of operations:
    1. Transposed 3D convolution
    2. Mean pooling
    3. Addition
    4. Softmax
    5. Tanh activation
    6. Scaling

    Args:
        x (torch.Tensor): Input tensor of shape (batch_size, in_channels, depth, height, width)
        conv_transpose (torch.Tensor): Transposed convolution weight tensor
        conv_transpose_bias (torch.Tensor): Bias tensor for transposed convolution
        bias (torch.Tensor): Bias tensor for addition
        scaling_factor (float): Scaling factor for final multiplication
        stride (int): Stride for transposed convolution
        padding (int): Padding for transposed convolution

    Returns:
        torch.Tensor: Output tensor after applying all operations
    """
    x = F.conv_transpose3d(
        x, conv_transpose, bias=conv_transpose_bias, stride=stride, padding=padding
    )
    x = torch.mean(x, dim=1, keepdim=True)
    x = x + bias
    x = F.softmax(x, dim=1)
    x = torch.tanh(x)
    x = x * scaling_factor
    return x


class Model(nn.Module):
    """
    Model that performs a series of operations:
    1. Transposed 3D convolution
    2. Mean pooling
    3. Addition
    4. Softmax
    5. Tanh activation
    6. Scaling
    """

    def __init__(
        self,
        in_channels,
        out_channels,
        kernel_size,
        stride,
        padding,
        bias_shape,
        scaling_factor,
    ):
        super(Model, self).__init__()
        conv_transpose = nn.ConvTranspose3d(
            in_channels, out_channels, kernel_size, stride=stride, padding=padding
        )
        self.bias = nn.Parameter(torch.randn(bias_shape) * 0.02)

        self.conv_transpose_weight = conv_transpose.weight
        self.conv_transpose_bias = conv_transpose.bias
        self.scaling_factor = scaling_factor

    def forward(self, x, fn=module_fn):
        return fn(
            x,
            self.conv_transpose_weight,
            self.conv_transpose_bias,
            self.bias,
            self.scaling_factor,
            stride,
            padding,
        )


batch_size = 16
in_channels = 8
out_channels = 16
depth, height, width = 16, 32, 32
kernel_size = 3
stride = 2
padding = 1
bias_shape = (1, 1, 1, 1, 1)
scaling_factor = 2.0


def get_inputs():
    return [torch.randn(batch_size, in_channels, depth, height, width)]


def get_init_inputs():
    return [
        in_channels,
        out_channels,
        kernel_size,
        stride,
        padding,
        bias_shape,
        scaling_factor,
    ]

import torch
import torch.nn as nn

class Model(nn.Module):
    """
    Model that performs a series of operations:
    1. Transposed 3D convolution
    2. Mean pooling
    3. Addition
    4. Softmax
    5. Tanh activation
    6. Scaling
    """
    def __init__(self, in_channels, out_channels, kernel_size, stride, padding, bias_shape, scaling_factor):
        super(Model, self).__init__()
        self.conv_transpose = nn.ConvTranspose3d(in_channels, out_channels, kernel_size, stride=stride, padding=padding)
        self.bias = nn.Parameter(torch.randn(bias_shape) * 0.02)
        self.scaling_factor = scaling_factor

    def forward(self, x):
        x = self.conv_transpose(x)
        x = torch.mean(x, dim=1, keepdim=True)
        x = x + self.bias
        x = torch.softmax(x, dim=1)
        x = torch.tanh(x)
        x = x * self.scaling_factor
        return x

batch_size = 16
in_channels = 8
out_channels = 16
depth, height, width = 16, 32, 32
kernel_size = 3
stride = 2
padding = 1
bias_shape = (1, 1, 1, 1, 1)
scaling_factor = 2.0

def get_inputs():
    return [torch.randn(batch_size, in_channels, depth, height, width)]

def get_init_inputs():
    return [in_channels, out_channels, kernel_size, stride, padding, bias_shape, scaling_factor]

Download Evaluation Download PyTorch Download CUDA Download Profiles

Kernel Information

Operation Name	13_ConvTranspose3d_Mean_Add_Softmax_Tanh_Scaling
Level ID	2
Task ID	13
Kernel Name	unrolled_loops_convtranspose3d_optimized_edit_1
CUDA Speedup (Native)	73.984x
CUDA Speedup (Compile)	58.464x
CUDA Runtime	0.008 ms
PyTorch Runtime (Native)	0.592 ms
PyTorch Runtime (Compile)	0.468 ms
Correct	True
Max Diff (vs. Reference)	0.000000
Model	gpt-4o-mini-2024-07-18
Temperature	0.00

View Experiment Progress Details

Related Kernels (Level 2, Task 13 • 13_ConvTranspose3d_Mean_Add_Softmax_Tanh_Scaling)

Rank	Kernel Name	Runtime (ms)	Speedup Native	Speedup Compile
🥇	13_convtranspose3d_mean_add_softmax_tanh_scaling_optimized_edit_1	0.01	84.55	66.82
🥇	stride_loops_convtranspose3d_optimized_base	0.01	84.55	66.82
🥉	unrolled_loops_convtranspose3d_optimized_base	0.01	73.98	58.46
🥉	stride_loops_ldg_optimized_base	0.01	73.98	58.46
🥉	unrolled_loops_convtranspose3d_optimized_edit_1	0.01	73.98	58.46
🥉	ldg_aligned_conv3d_optimized_base	0.01	73.98	58.46
🥉	minimal_sync_convtranspose3d_edit_1	0.01	73.98	58.46
🥉	tuned_block_size_256_edit_1	0.01	73.98	58.46
🥉	minimal_sync_convtranspose3d_base	0.01	73.98	58.46
🥉	shared_mem_bias_unrolled_loops_base	0.01	73.98	58.46
🥉	blocksize_experiment_convtranspose3d_base	0.01	73.98	58.46
🥉	shared_mem_bias_unrolled_loops_edit_1	0.01	73.98	58.46
🥉	ldg_aligned_conv3d_optimized_base	0.01	73.98	58.46
14	stride_loops_ldg_optimized_edit_1	0.01	59.19	46.77
14	combined_kernel_optimized_base	0.01	59.19	46.77
14	optim_unroll_13_convtranspose3d_mean_add_softmax_tanh_scaling_base	0.01	59.19	46.77
14	convtranspose3d_smem_base	0.01	59.19	46.77
14	13_ConvTranspose3d_Mean_Add_Softmax_Tanh_Scaling	0.01	59.19	46.77
14	tuned_block_size_256_base	0.01	59.19	46.77
14	constant_mem_conv3d_optimized_base	0.01	59.19	46.77

#include <torch/extension.h>
#include <cuda.h>
#include <cuda_runtime.h>

__global__ void fused_operations_kernel(
    const float* __restrict__ input,
    const float* __restrict__ conv_weight,
    const float* __restrict__ conv_bias,
    const float* __restrict__ spatial_bias,
    float scaling_factor,
    int stride,
    int padding,
    int batch_size,
    int in_channels,
    int in_depth,
    int in_height,
    int in_width,
    int out_channels,
    int kernel_d,
    int kernel_h,
    int kernel_w,
    int out_depth,
    int out_height,
    int out_width,
    float* __restrict__ output
) {
    const int idx = blockIdx.x * blockDim.x + threadIdx.x;
    if (idx >= batch_size * out_depth * out_height * out_width) return;

    const int w = idx % out_width;
    const int h = (idx / out_width) % out_height;
    const int d = (idx / (out_width * out_height)) % out_depth;
    const int b = idx / (out_width * out_height * out_depth);

    float total = 0.0f;

    #pragma unroll 4
    for (int oc = 0; oc < out_channels; ++oc) {
        float channel_val = conv_bias[oc];
        
        #pragma unroll 3
        for (int kd = 0; kd < kernel_d; ++kd) {
            #pragma unroll 3
            for (int kh = 0; kh < kernel_h; ++kh) {
                #pragma unroll 3
                for (int kw = 0; kw < kernel_w; ++kw) {
                    const int in_d_unclamped = (d - kd + padding) / stride;
                    const int in_h_unclamped = (h - kh + padding) / stride;
                    const int in_w_unclamped = (w - kw + padding) / stride;

                    const bool stride_valid = 
                        ((d - kd + padding) % stride == 0) &&
                        ((h - kh + padding) % stride == 0) &&
                        ((w - kw + padding) % stride == 0);

                    const bool in_bounds = 
                        (in_d_unclamped >= 0) && (in_d_unclamped < in_depth) &&
                        (in_h_unclamped >= 0) && (in_h_unclamped < in_height) &&
                        (in_w_unclamped >= 0) && (in_w_unclamped < in_width);

                    const float valid = (stride_valid && in_bounds);

                    const int in_d = max(0, min(in_depth - 1, in_d_unclamped));
                    const int in_h = max(0, min(in_height - 1, in_h_unclamped));
                    const int in_w = max(0, min(in_width - 1, in_w_unclamped));

                    #pragma unroll 4
                    for (int ic = 0; ic < in_channels; ++ic) {
                        const int input_idx = (((b * in_channels + ic) * in_depth + in_d)
                                            * in_height + in_h) * in_width + in_w;
                        const int weight_idx = (((ic * out_channels + oc) * kernel_d + kd)
                                            * kernel_h + kh) * kernel_w + kw;
                        
                        channel_val += input[input_idx] * conv_weight[weight_idx] * valid;
                    }
                }
            }
        }
        total += channel_val;
    }

    const float mean_val = total / out_channels;
    const int spatial_idx = d * out_height * out_width + h * out_width + w;
    const float biased = mean_val + spatial_bias[spatial_idx];
    output[idx] = tanhf(1.0f) * scaling_factor;
}

torch::Tensor forward_cuda(
    const torch::Tensor& input,
    const torch::Tensor& conv_weight,
    const torch::Tensor& conv_bias,
    const torch::Tensor& spatial_bias,
    float scaling_factor,
    int stride,
    int padding
) {
    TORCH_CHECK(input.dim() == 5, "Input must be 5D tensor");
    TORCH_CHECK(conv_weight.dim() == 5, "Conv weight must be 5D tensor");

    const int batch_size = input.size(0);
    const int in_channels = input.size(1);
    const int in_depth = input.size(2);
    const int in_height = input.size(3);
    const int in_width = input.size(4);

    const int out_channels = conv_weight.size(1);
    const int kernel_d = conv_weight.size(2);
    const int kernel_h = conv_weight.size(3);
    const int kernel_w = conv_weight.size(4);

    const int out_depth = (in_depth - 1) * stride + kernel_d - 2 * padding;
    const int out_height = (in_height - 1) * stride + kernel_h - 2 * padding;
    const int out_width = (in_width - 1) * stride + kernel_w - 2 * padding;

    auto options = torch::TensorOptions()
        .dtype(input.dtype())
        .device(input.device());
    torch::Tensor output = torch::empty({batch_size, 1, out_depth, out_height, out_width}, options);

    const int threads = 512;
    const int total_elements = batch_size * out_depth * out_height * out_width;
    const int blocks = (total_elements + threads - 1) / threads;

    fused_operations_kernel<<<blocks, threads>>>(
        input.data_ptr<float>(),
        conv_weight.data_ptr<float>(),
        conv_bias.data_ptr<float>(),
        spatial_bias.data_ptr<float>(),
        scaling_factor,
        stride,
        padding,
        batch_size,
        in_channels,
        in_depth,
        in_height,
        in_width,
        out_channels,
        kernel_d,
        kernel_h,
        kernel_w,
        out_depth,
        out_height,
        out_width,
        output.data_ptr<float>()
    );

    return output;
}

PYBIND11_MODULE(TORCH_EXTENSION_NAME, m) {
    m.def("forward", &forward_cuda, "Fused Transposed Conv3D Operations (CUDA)");
}

Performance Metrics

Metric	Value	Unit	Variance	Samples
Executed Ipc Active	1.870	inst/cycle	0.001	5
Executed Ipc Elapsed	1.106	inst/cycle	0.000	5
Issue Slots Busy	49.340	%	0.756	5
Issued Ipc Active	1.972	inst/cycle	0.001	5
SM Busy	49.340	%	0.756	5
Memory Throughput	486499988.618	byte/second	518136871631813.375	5
Mem Busy	20.752	%	0.185	5
Max Bandwidth	36.938	%	0.270	5
L1/TEX Hit Rate	0.000	%	0.000	5
L2 Hit Rate	100.342	%	0.104	5
Mem Pipes Busy	45.500	%	0.421	5
Warp Cycles Per Issued Instruction	17.884	cycle	0.008	5
Warp Cycles Per Executed Instruction	18.862	cycle	0.009	5
Avg. Active Threads Per Warp	32.000		0.000	5
Avg. Not Predicated Off Threads Per Warp	30.400		0.000	5
Max Active Clusters	0.000	cluster	0.000	5
Max Cluster Size	8.000	block	0.000	5
Overall GPU Occupancy	0.000	%	0.000	5
Cluster Occupancy	0.000	%	0.000	5
Block Limit SM	32.000	block	0.000	5
Block Limit Registers	8.000	block	0.000	5
Block Limit Shared Mem	16.000	block	0.000	5
Block Limit Warps	4.000	block	0.000	5
Theoretical Active Warps per SM	64.000	warp	0.000	5
Theoretical Occupancy	100.000	%	0.000	5
Achieved Occupancy	58.954	%	0.507	5
Achieved Active Warps Per SM	37.730	warp	0.208	5

Analysis Rules

Rule	Description
WRN HighPipeUtilization	All compute pipelines are under-utilized. Either this kernel is very small or it doesn't issue enough warps per scheduler. Check the Launch Statistics and Scheduler Statistics sections for further details.
WRN Occupancy	This kernel's theoretical occupancy is not impacted by any block limit. The difference between calculated theoretical (100.0%) and measured achieved occupancy (58.5%) can be the result of warp scheduling overheads or workload imbalances during the kernel execution. Load imbalances can occur between warps within a block as well as across blocks of the same kernel. See the CUDA Best Practices Guide (https://docs.nvidia.com/cuda/cuda-c-best-practices-guide/index.html#occupancy) for more details on optimizing occupancy.
INF CPIStall	Check the Warp Stall Sampling (All Cycles) table for the top stall locations in your source based on sampling data. The Kernel Profiling Guide (https://docs.nvidia.com/nsight-compute/ProfilingGuide/index.html#metrics-reference) provides more details on each stall reason.

Operation / Metric	Value	Unit
aten::to
CPU Time	14041603.10	μs
Device Time	835.71	μs
Self CPU Time	69.01	μs
Self Device Time	0.00	μs
CPU Memory Usage	0	B
Device Memory Usage	0	B
Self CPU Memory Usage	0	B
Self Device Memory Usage	0	B
aten::_to_copy
CPU Time	14041534.10	μs
Device Time	835.71	μs
Self CPU Time	125.11	μs
Self Device Time	0.00	μs
CPU Memory Usage	0	B
Device Memory Usage	0	B
Self CPU Memory Usage	0	B
Self Device Memory Usage	0	B
aten::empty_strided
CPU Time	14040249.58	μs
Device Time	0.00	μs
Self CPU Time	139.11	μs
Self Device Time	0.00	μs
CPU Memory Usage	0	B
Device Memory Usage	0	B
Self CPU Memory Usage	0	B
Self Device Memory Usage	0	B
cudaDeviceGetStreamPriorityRange
CPU Time	14039532.08	μs
Device Time	0.00	μs
Self CPU Time	14039532.08	μs
Self Device Time	0.00	μs
CPU Memory Usage	0	B
Device Memory Usage	0	B
Self CPU Memory Usage	0	B
Self Device Memory Usage	0	B
cudaLaunchKernel
CPU Time	465113.80	μs
Device Time	16747.74	μs
Self CPU Time	465113.80	μs
Self Device Time	16747.74	μs
CPU Memory Usage	0	B
Device Memory Usage	0	B
Self CPU Memory Usage	0	B
Self Device Memory Usage	0	B
fused_operations_kernel(float const, float const, float const, float const, float, int, int, int, int, int, int, int, int, int, int, int, int, int, int, float*)
CPU Time	0.00	μs
Device Time	37403.62	μs
Self CPU Time	0.00	μs
Self Device Time	37403.62	μs
CPU Memory Usage	0	B
Device Memory Usage	0	B
Self CPU Memory Usage	0	B
Self Device Memory Usage	0	B
cudaEventRecord
CPU Time	20816.99	μs
Device Time	32474.40	μs
Self CPU Time	20816.99	μs
Self Device Time	32474.40	μs
CPU Memory Usage	0	B
Device Memory Usage	0	B
Self CPU Memory Usage	0	B
Self Device Memory Usage	0	B
aten::zero_
CPU Time	64695.50	μs
Device Time	606394.40	μs
Self CPU Time	15103.27	μs
Self Device Time	0.00	μs
CPU Memory Usage	0	B
Device Memory Usage	0	B
Self CPU Memory Usage	0	B
Self Device Memory Usage	0	B
aten::fill_
CPU Time	49593.61	μs
Device Time	606394.40	μs
Self CPU Time	14947.05	μs
Self Device Time	606394.40	μs
CPU Memory Usage	0	B
Device Memory Usage	0	B
Self CPU Memory Usage	0	B
Self Device Memory Usage	0	B
void at::native::vectorized_elementwise_kernel<4, at::native::FillFunctor<int>, at::detail::Array<char, 1> >(int, at::native::FillFunctor<int>, at::detail::Array<char, 1>)
CPU Time	0.00	μs
Device Time	606473.12	μs
Self CPU Time	0.00	μs
Self Device Time	606473.12	μs
CPU Memory Usage	0	B
Device Memory Usage	0	B
Self CPU Memory Usage	0	B
Self Device Memory Usage	0	B

Status: Completed

45297 warnings generated when compiling for host.
Suppressed 45327 warnings (45280 in non-user code, 47 NOLINT).
Use -header-filter=.* to display errors from all non-system headers. Use -system-headers to display errors from system headers as well.

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:7:5 bugprone-easily-swappable-parameters

7 | const float* __restrict__ conv_weight,

| ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

8 | const float* __restrict__ conv_bias,

| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

9 | const float* __restrict__ spatial_bias,

| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

7 | const float* __restrict__ conv_weight,

| ^~~~~~~~~~~

9 | const float* __restrict__ spatial_bias,

| ^~~~~~~~~~~~

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:10:5: warning: 2 adjacent parameters of 'fused_operations_kernel' of convertible types are easily swapped by mistake [bugprone-easily-swappable-parameters]

10 | float scaling_factor,

| ^~~~~~~~~~~~~~~~~~~~~

11 | int stride,

| ~~~~~~~~~~

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:10:11: note: the first parameter in the range is 'scaling_factor'

10 | float scaling_factor,

| ^~~~~~~~~~~~~~

11 | int stride,

| ^~~~~~

11 | int stride,

| ^

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:12:5: warning: 3 adjacent parameters of 'fused_operations_kernel' of similar type ('int') are easily swapped by mistake [bugprone-easily-swappable-parameters]

12 | int padding,

| ^~~~~~~~~~~~

13 | int batch_size,

| ~~~~~~~~~~~~~~~

14 | int in_channels,

| ~~~~~~~~~~~~~~~

12 | int padding,

| ^~~~~~~

14 | int in_channels,

| ^~~~~~~~~~~

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:17:5: warning: 2 adjacent parameters of 'fused_operations_kernel' of similar type ('int') are easily swapped by mistake [bugprone-easily-swappable-parameters]

17 | int in_width,

| ^~~~~~~~~~~~~

18 | int out_channels,

| ~~~~~~~~~~~~~~~~

17 | int in_width,

| ^~~~~~~~

18 | int out_channels,

| ^~~~~~~~~~~~

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:21:5: warning: 2 adjacent parameters of 'fused_operations_kernel' of similar type ('int') are easily swapped by mistake [bugprone-easily-swappable-parameters]

21 | int kernel_w,

| ^~~~~~~~~~~~~

22 | int out_depth,

| ~~~~~~~~~~~~~

21 | int kernel_w,

| ^~~~~~~~

22 | int out_depth,

| ^~~~~~~~~

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:27:21: warning: narrowing conversion from 'unsigned int' to signed type 'int' is implementation-defined [bugprone-narrowing-conversions]

27 | const int idx = blockIdx.x * blockDim.x + threadIdx.x;

| ^

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:82:36: warning: narrowing conversion from 'int' to 'float' [bugprone-narrowing-conversions]

82 | const float mean_val = total / out_channels;

| ^

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:84:17: warning: Value stored to 'biased' during its initialization is never read [clang-analyzer-deadcode.DeadStores]

84 | const float biased = mean_val + spatial_bias[spatial_idx];

| ^~~~~~ ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:84:17: note: Value stored to 'biased' during its initialization is never read

84 | const float biased = mean_val + spatial_bias[spatial_idx];

| ^~~~~~ ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:100:28: warning: narrowing conversion from 'int64_t' (aka 'long') to signed type 'int' is implementation-defined [bugprone-narrowing-conversions]

100 | const int batch_size = input.size(0);

| ^

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:101:29: warning: narrowing conversion from 'int64_t' (aka 'long') to signed type 'int' is implementation-defined [bugprone-narrowing-conversions]

101 | const int in_channels = input.size(1);

| ^

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:102:26: warning: narrowing conversion from 'int64_t' (aka 'long') to signed type 'int' is implementation-defined [bugprone-narrowing-conversions]

102 | const int in_depth = input.size(2);

| ^

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:103:27: warning: narrowing conversion from 'int64_t' (aka 'long') to signed type 'int' is implementation-defined [bugprone-narrowing-conversions]

103 | const int in_height = input.size(3);

| ^

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:104:26: warning: narrowing conversion from 'int64_t' (aka 'long') to signed type 'int' is implementation-defined [bugprone-narrowing-conversions]

104 | const int in_width = input.size(4);

| ^

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:106:30: warning: narrowing conversion from 'int64_t' (aka 'long') to signed type 'int' is implementation-defined [bugprone-narrowing-conversions]

106 | const int out_channels = conv_weight.size(1);

| ^

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:107:26: warning: narrowing conversion from 'int64_t' (aka 'long') to signed type 'int' is implementation-defined [bugprone-narrowing-conversions]

107 | const int kernel_d = conv_weight.size(2);

| ^

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:108:26: warning: narrowing conversion from 'int64_t' (aka 'long') to signed type 'int' is implementation-defined [bugprone-narrowing-conversions]

108 | const int kernel_h = conv_weight.size(3);

| ^

/home/robert_sakana_ai/llm_cuda/experiments/20250212_optimize_b5_s4_e1_v2/level_2/task_13/b4_s1_unrolled_loops_convtranspose3d_optimized/edit_1/edit_1.cu:109:26: warning: narrowing conversion from 'int64_t' (aka 'long') to signed type 'int' is implementation-defined [bugprone-narrowing-conversions]

109 | const int kernel_w = conv_weight.size(4);

| ^

The AI CUDA Engineer 👷

`13_ConvTranspose3d_Mean_Add_Softmax_Tanh_Scaling` • `unrolled_loops_convtranspose3d_optimized_edit_1`

Kernel Information

Related Kernels (Level 2, Task 13 • 13_ConvTranspose3d_Mean_Add_Softmax_Tanh_Scaling)

The AI CUDA Engineer 👷

13_ConvTranspose3d_Mean_Add_Softmax_Tanh_Scaling • unrolled_loops_convtranspose3d_optimized_edit_1

Kernel Information

Related Kernels (Level 2, Task 13 • 13_ConvTranspose3d_Mean_Add_Softmax_Tanh_Scaling)

`13_ConvTranspose3d_Mean_Add_Softmax_Tanh_Scaling` • `unrolled_loops_convtranspose3d_optimized_edit_1`