Modern embedding strategies for PyTorch — the ones missing from torch.nn.
torch.nn gives you nn.Embedding (a lookup table). That's it. The moment you work with continuous inputs, modern transformer architectures, coordinates, time, or tabular data, you're on your own — copy-pasting RoPE implementations across projects. torchembed is a single, well-tested, pip-installable home for all of them.
torchembed is integrated into DeepSpeed and ships as a dependency. The fused RoPE kernel is used by DeepSpeed's transformer engine for accelerated attention.
- Positional embeddings —
RotaryEmbedding(RoPE, LLaMA/Mistral-style),ALiBiEmbedding(long-context extrapolation),SinusoidalEmbedding,LearnedPositionalEmbedding. - Fourier features —
RandomFourierFeatures(coordinate/kernel encoding),LearnedFourierFeatures,GaussianFourierProjection(diffusion timestep embedding). - Categorical embeddings —
EntityEmbeddingandMultiCategoricalEmbeddingfor tabular data, with auto-sized embedding dimensions. - Patch embeddings —
PatchEmbedding(ViT) andTubeletEmbedding(video transformers: VideoMAE, ViViT). - Temporal embeddings —
CyclicEmbedding,TimestampEmbedding,FrequencyEmbeddingfor hour/day/month and periodic time series. - Fused Triton kernels — optional GPU-accelerated RoPE, ~4x faster than plain PyTorch and ~2x faster than
torch.compile, with full autograd support and automatic CPU fallback. - Zero required dependencies beyond PyTorch — no transformers, no numpy, nothing pulled in you didn't ask for.
pip install torchembedFor GPU-accelerated kernels:
pip install torchembed[triton]Requires Python >= 3.9 and PyTorch >= 2.0.
torchembed includes optional Triton-accelerated kernels for GPU. Install with pip install torchembed[triton], then enable with use_fused=True:
rope = RotaryEmbedding(dim=64, use_fused=True)The fused RoPE kernel combines cos/sin lookup, rotate-half, and element-wise multiplication into a single Triton launch, reducing memory traffic. Supports any even dim (32, 64, 128, etc.) and full autograd support. Falls back to vanilla PyTorch automatically when Triton is unavailable or inputs are on CPU.
RoPE forward pass on NVIDIA GB10 (float16):
| Shape (B,H,S,D,rot) | PyTorch (ms) | torch.compile (ms) | Triton (ms) | Speedup |
|---|---|---|---|---|
| (1,32,2048,128,128) | 1.40 | 0.61 | 0.34 | 4.15x |
| (1,32,4096,128,128) | 2.95 | 1.21 | 0.63 | 4.68x |
| (1,32,8192,128,128) | 5.94 | 2.47 | 1.29 | 4.62x |
| (2,32,2048,128,128) | 2.97 | 1.23 | 0.75 | 3.98x |
| (1,32,2048,256,128) | 2.87 | 1.24 | 0.66 | 4.34x |
The fused Triton kernel is ~4x faster than pure PyTorch and ~2x faster than torch.compile. torch.compile reduces overhead but cannot eliminate intermediate tensor allocations from chunk/cat — the fused kernel reads and writes each element exactly once.
import torch
from torchembed.positional import RotaryEmbedding
rope = RotaryEmbedding(dim=64) # head_dim
# Inside your attention layer:
q = torch.randn(batch, heads, seq_len, 64)
k = torch.randn(batch, heads, seq_len, 64)
q, k = rope(q, k) # apply rotation in-placeRoPE has no trainable parameters and preserves vector norms (it's a pure rotation).
The default base of 10,000 matches the original paper; use base=500_000 for LLaMA 3.
For GPU-accelerated inference:
rope = RotaryEmbedding(dim=128, use_fused=True).to("cuda")
q, k = rope(q.cuda(), k.cuda())from torchembed.positional import ALiBiEmbedding
alibi = ALiBiEmbedding(num_heads=8)
# After computing raw attention scores:
attn_scores = q @ k.transpose(-2, -1) / math.sqrt(head_dim)
attn_scores = alibi(attn_scores) # adds learned distance penalty
attn_weights = attn_scores.softmax(-1)from torchembed.fourier import GaussianFourierProjection
import torch.nn as nn
class DiffusionTimeEmbedding(nn.Module):
def __init__(self, embed_dim):
super().__init__()
self.fourier = GaussianFourierProjection(embed_dim=embed_dim, scale=16)
self.mlp = nn.Sequential(
nn.Linear(embed_dim, embed_dim * 4),
nn.SiLU(),
nn.Linear(embed_dim * 4, embed_dim),
)
def forward(self, t):
return self.mlp(self.fourier(t))
t_emb = DiffusionTimeEmbedding(embed_dim=256)
t = torch.rand(32) # normalized timesteps
emb = t_emb(t) # (32, 256) — condition your UNet on thisfrom torchembed.patch import PatchEmbedding
patch_emb = PatchEmbedding(
image_size=224,
patch_size=16,
embed_dim=768,
)
images = torch.randn(4, 3, 224, 224)
tokens = patch_emb(images) # (4, 196, 768)
print(patch_emb.num_patches) # 196from torchembed.patch import TubeletEmbedding
tubelet_emb = TubeletEmbedding(
image_size=224,
patch_size=16,
tubelet_size=2,
embed_dim=768,
)
video = torch.randn(2, 3, 16, 224, 224) # (B, C, T, H, W)
tokens = tubelet_emb(video) # (2, 1568, 768)
# 1568 = (16/2) * (224/16) * (224/16) = 8 * 14 * 14from torchembed.categorical import MultiCategoricalEmbedding
# A tabular dataset with 3 categorical columns:
# country (50 unique values), day of week (7), product category (120)
emb = MultiCategoricalEmbedding(cardinalities=[50, 7, 120])
print(emb.output_dim) # sum of auto-sized embed dims
x = torch.stack([country_ids, dow_ids, category_ids], dim=1) # (batch, 3)
features = emb(x) # (batch, output_dim)from torchembed.temporal import CyclicEmbedding
import torch
hour_enc = CyclicEmbedding(period=24)
dow_enc = CyclicEmbedding(period=7)
month_enc = CyclicEmbedding(period=12)
hour = torch.tensor([0.0, 6.0, 12.0, 18.0])
dow = torch.tensor([0.0, 1.0, 2.0, 3.0])
month = torch.tensor([1.0, 4.0, 7.0, 10.0])
time_features = torch.cat([
hour_enc(hour), # (4, 2)
dow_enc(dow), # (4, 2)
month_enc(month), # (4, 2)
], dim=-1) # (4, 6)from torchembed.fourier import RandomFourierFeatures
# Encode 2D spatial coordinates for a neural field / NeRF-style model
rff = RandomFourierFeatures(in_features=2, out_features=256, sigma=1.0)
coords = torch.rand(1024, 2) # (x, y) pairs in [0, 1]
features = rff(coords) # (1024, 256)from torchembed.temporal import FrequencyEmbedding
# Discover periodic structure in time series automatically
freq_emb = FrequencyEmbedding(embed_dim=32)
t = torch.linspace(0, 100, 512).unsqueeze(0) # (1, 512) time steps
out = freq_emb(t) # (1, 512, 33)
# 33 = 1 linear trend + 32 sinusoidal componentsFull API reference: liodon-ai.github.io/torchembed. Hand-written guides for each module are in docs/:
| Module | Guide |
|---|---|
| Positional (RoPE, ALiBi, Sinusoidal, Learned) | docs/positional.md |
| Fourier features | docs/fourier.md |
| Categorical embeddings | docs/categorical.md |
| Patch embeddings (ViT, video) | docs/patch.md |
| Temporal embeddings | docs/temporal.md |
pip install torchembed[dev]
pytestBuilding API docs:
make docs # generates docs/api/
make docs-serve # serves at http://localhost:8080API docs are generated from Google-style docstrings using pdoc.
Contributions welcome! If there's an embedding strategy you find yourself copy-pasting into projects, open a PR with a clear docstring (paper reference included), tests covering shape/gradients/key mathematical properties, and a README example.
MIT