Instructions to use Quazim0t0/Escarda-86M-Base-JL with libraries, inference providers, notebooks, and local apps. Follow these links to get started.
- Libraries
- Transformers
How to use Quazim0t0/Escarda-86M-Base-JL with Transformers:
# Use a pipeline as a high-level helper from transformers import pipeline pipe = pipeline("text-generation", model="Quazim0t0/Escarda-86M-Base-JL", trust_remote_code=True)# Load model directly from transformers import AutoModel model = AutoModel.from_pretrained("Quazim0t0/Escarda-86M-Base-JL", trust_remote_code=True, dtype="auto") - Notebooks
- Google Colab
- Kaggle
- Local Apps Settings
- vLLM
How to use Quazim0t0/Escarda-86M-Base-JL with vLLM:
Install from pip and serve model
# Install vLLM from pip: pip install vllm # Start the vLLM server: vllm serve "Quazim0t0/Escarda-86M-Base-JL" # Call the server using curl (OpenAI-compatible API): curl -X POST "http://localhost:8000/v1/completions" \ -H "Content-Type: application/json" \ --data '{ "model": "Quazim0t0/Escarda-86M-Base-JL", "prompt": "Once upon a time,", "max_tokens": 512, "temperature": 0.5 }'Use Docker
docker model run hf.co/Quazim0t0/Escarda-86M-Base-JL
- SGLang
How to use Quazim0t0/Escarda-86M-Base-JL with SGLang:
Install from pip and serve model
# Install SGLang from pip: pip install sglang # Start the SGLang server: python3 -m sglang.launch_server \ --model-path "Quazim0t0/Escarda-86M-Base-JL" \ --host 0.0.0.0 \ --port 30000 # Call the server using curl (OpenAI-compatible API): curl -X POST "http://localhost:30000/v1/completions" \ -H "Content-Type: application/json" \ --data '{ "model": "Quazim0t0/Escarda-86M-Base-JL", "prompt": "Once upon a time,", "max_tokens": 512, "temperature": 0.5 }'Use Docker images
docker run --gpus all \ --shm-size 32g \ -p 30000:30000 \ -v ~/.cache/huggingface:/root/.cache/huggingface \ --env "HF_TOKEN=<secret>" \ --ipc=host \ lmsysorg/sglang:latest \ python3 -m sglang.launch_server \ --model-path "Quazim0t0/Escarda-86M-Base-JL" \ --host 0.0.0.0 \ --port 30000 # Call the server using curl (OpenAI-compatible API): curl -X POST "http://localhost:30000/v1/completions" \ -H "Content-Type: application/json" \ --data '{ "model": "Quazim0t0/Escarda-86M-Base-JL", "prompt": "Once upon a time,", "max_tokens": 512, "temperature": 0.5 }' - Docker Model Runner
How to use Quazim0t0/Escarda-86M-Base-JL with Docker Model Runner:
docker model run hf.co/Quazim0t0/Escarda-86M-Base-JL
Escarda-86M-Base
π Jet-Long context extension (native 4K β 10K)
This is the Jet-Long edition of Escarda-86M-Base.
It extends the usable context from the native 4,096-token training window to
10,240 tokens with no fine-tuning and no change to short-context behaviour,
by adding dynamic bifocal RoPE from Jet-Long (arXiv:2607.07740, NVIDIA).
What was applied
Jet-Long pairs a local window (w0 = 2048, classic RoPE) with a remote window
whose position map aliases far-apart tokens back onto the pretrained rotation grid:
f(x) = floor(x / G), G = max(1, ceil(L / 4096))
G adapts to the current sequence length L, so:
L β€ 4096βG = 1β f is the identity β the model is bit-for-bit the base model. (Verified: max |Ξlogit| between Jet-Long on/off within the window is0.000e+00.)L > 4096β the remote window keeps every rotation in-distribution, so the model extrapolates instead of collapsing.
Implementation notes specific to this SpikeWhaleLM build:
- Only the decoupled RoPE partition (16 of 64 head dims) is aliased; the NoPE partition
is untouched. Softmax attention (
use_derf=False) β the standard Jet-Long merge applies. - The remote view is realized by an on-the-fly correction rotation on the already-RoPE'd KV cache (RoPE composes additively), so the cache is never rewritten and decode is cheap.
- Enabled via config:
use_jetlong=true,jetlong_w0=2048,jetlong_w_pretrained=4096,max_position_embeddings=10240. Setuse_jetlong=falseto recover the exact base model. - The inclusionβexclusion / CuTe throughput kernel from the paper is not included (it targets 100K+ contexts on H100); at 86M params the bifocal attention is computed directly.
Measured (PG-19-style perplexity on held-out text, lower is better)
| Context length | Base model | This Jet-Long model |
|---|---|---|
| β€ 4,096 (in-window) | (identical β Jet-Long is a no-op) | (identical) |
| 10,240 | 59.68 | 16.04 |
Beyond the training window the base model's perplexity blows up while Jet-Long stays flat β and long-context generation stays grammatical where the base model degrades into word-salad.
Usage
Jet-Long is on by default in this repo. Pass explicit position_ids so RoPE gets true
absolute positions during cached decode:
import torch
from transformers import AutoModelForCausalLM
m = AutoModelForCausalLM.from_pretrained("Quazim0t0/Escarda-86M-Base-JL", trust_remote_code=True)
ids = ... # up to ~10,240 tokens
pos = torch.arange(ids.shape[1]).unsqueeze(0)
out = m(input_ids=ids, position_ids=pos, use_cache=True) # prefill, then decode step-by-step
Method: Tang, Wang, Gu, Han, Cai β βJet-Long: Efficient Long-Context Extension with Dynamic Bifocal RoPEβ, arXiv:2607.07740. Applied here zero-shot to SpikeWhaleLM; no weights were retrained.
Escarda-86M-Base is a ~86M-parameter, from-scratch decoder-only language model β the
base sibling of Quazim0t0/Escarda-86M
(the chat-tuned model). It shares the same SpikeWhaleLM architecture (Multi-head Latent
Attention, an n-gram "engram" memory, hash-lookup layers, hyper-connections, an HRM
refinement step, and JEPA / multi-token-prediction training objectives) and the same
custom ChatML-aware tokenizer.
This checkpoint is a JEPA-distilled base. It is best used as a starting point for continued pretraining / fine-tuning rather than as a chat assistant.
Related models: SFT / chat model β Quazim0t0/Escarda-86M Β· live demo β Escarda-86M-Chat Space
Trained using Modal's credits during the Small Models, Big Adventures Hackathon.
Model summary
| Parameters | ~85.7M (tie_word_embeddings=True) |
| Type | Decoder-only LM (SpikeWhaleLM, model_type: spike_whale) |
| Hidden size / layers | 640 / 16 |
| Attention | 10 heads (head_dim=64), 1 KV head (MQA), MLA low-rank Q/O, decoupled RoPE(16)+NoPE(48), QK-norm |
| Context length | 4096 tokens |
| Vocab | 16,512 (custom length-max tokenizer) |
| License | Apache-2.0 |
For the full architecture description see the chat model's card.
Architecture
These models are built on SpikeWhaleLM, a custom ~86M-parameter decoder-only transformer (16 layers, hidden size 640, 4096-token context, 16,512 vocab, tied input/output embeddings). It combines several non-standard components:
- Multi-head Latent Attention (MLA + XSA) β queries and the output projection are LoRA-compressed (rank 128); each head splits into a decoupled RoPE part (dim 16) and a position-agnostic NoPE part (dim 48); 10 query heads share a single KV head (multi-query attention), with QK-norm for stable logits.
- Engram n-gram memory β a gated associative memory that hashes local n-grams (up to trigrams) into a learned 4,096-entry table and mixes the result back into the residual stream.
- Hash-lookup layers (Γ2) β multi-head content-addressable features alongside the token embeddings.
- Hyper-Connections β learned, width-expanded residual connections mixed via Sinkhorn-normalized routing, in place of the plain residual add.
- HRM refinement β a Hierarchical Reasoning Model block that performs an extra latent "think a bit more" refinement pass over the hidden states before the output head.
- Multi-Token Prediction (MTP) β a DeepSeek-V3-style auxiliary training head predicting more than one next token (no inference cost).
- Feed-forward is dense (the block is MoE-capable, but MoE is disabled in this release).
JEPA vs HRM. The Escarda models are trained with both HRM refinement and a JEPA (Joint-Embedding Predictive Architecture) auxiliary objective (
use_hrm_refine=True,use_jepa=True) β the JEPA term predicts future latent states during training to shape the model's representations. The sibling Byrne models drop JEPA and use HRM refinement only.
Tokenizer
These models use SpikeTokenizer, a custom byte-level "length-max" (greedy
longest-match) tokenizer with a 16,512-token vocabulary β not a standard BPE/HF
tokenizer. Text is UTF-8 encoded, each byte mapped to a latin-1 character, then greedily
matched against the vocab using the longest key that fits at each position. It is
ChatML-aware, with atomic special tokens for framing and reasoning/tool markers
(<|im_start|>, <|im_end|>, <think>/</think>, <begin_solution>/<end_solution>,
tool-call markers) plus <bos>/<eos>/<pad>/<unk>. It ships as a PreTrainedTokenizer
subclass (spike_tokenizer.py) and loads via
AutoTokenizer.from_pretrained(..., trust_remote_code=True).
Evaluation
splits. byte_ppl is exp(sum_NLL_nats / total_UTF8_bytes) on WikiText-2 test (tokenizer-
independent). BLiMP is fraction of minimal pairs with logprob(good) > logprob(bad)
(12 paradigms Γ 150). Stderr is binomial sqrt(p(1-p)/n).
Language modeling
| Metric | Value |
|---|---|
| WikiText-2 byte_ppl β | 2.2228 |
| BLiMP acc β | 0.7144 |
Multiple-choice suite
| Task | acc | Β± | acc_norm | Β± |
|---|---|---|---|---|
| arc_easy | 0.3801 | 0.0100 | 0.3615 | 0.0099 |
| arc_challenge | 0.1886 | 0.0114 | 0.2235 | 0.0122 |
| hellaswag | 0.2759 | 0.0045 | 0.2832 | 0.0045 |
| winogrande | 0.5162 | 0.0140 | β | β |
| piqa | 0.5843 | 0.0115 | 0.5631 | 0.0116 |
| openbookqa | 0.1300 | 0.0150 | 0.2500 | 0.0194 |
| boolq | 0.5138 | 0.0087 | β | β |
ArithMark-2.0 (AxiomicLabs)
| Metric | Value |
|---|---|
| acc | 0.2536 Β± 0.0087 |
| acc_norm | 0.2348 Β± 0.0085 |
n = 2,500 Β· chance = 0.25.
Note: as a distilled base, this checkpoint has the lowest byte-perplexity of the Escarda family but trades off downstream task accuracy β a good reminder that perplexity alone is not a reliable capability ranking. For the strongest chat behaviour use Escarda-86M; use this model when you want a low-loss base to continue pretraining or fine-tune.
Training & token budget
- Tokens: ~20B (from-scratch pretraining of the SpikeWhale base, ~28k steps); this checkpoint is a JEPA-distilled snapshot of that base.
- Token/param ratio: ~233 tokens/param (20B / 85.7M) β roughly 11β12Γ the Chinchilla ~20-tokens/param compute-optimal heuristic, i.e. a deliberately over-trained small model (the inference-efficient trade-off).
Fitting the Chinchilla data term to this model's own pretraining loss curve gives:
L(D) β 2.611 + 77,715 Β· D^(β0.537) (nats/token, RΒ² = 0.92)
From that fit:
- Compute-optimal tokens for this 86M size β 4.3B β the 20B run is ~4.6Γ past compute-optimal.
- Diminishing-returns knee β 22.5B tokens (where +1B tokens buys < 0.005 nats) β the 20B stopping point lands right at the knee, a well-judged budget.
- The model is parameter-bound, not data-bound at 20B: the capacity term (
0.82 nats) exceeds the data term (0.54), so extra tokens help little. Doubling to 40B is projected to lower loss only0.07 nats (7% perplexity) with negligible downstream gain β the lever for better quality is more parameters, not more tokens. (This is also why, as a distilled base, it reaches the lowest perplexity of the family without the best downstream scores β it is already at its data-term floor.)
Caveats: single-size fit (folds irreducible loss + capacity floor into one constant); the cosine-LR decay inflates the fitted exponent, so treat Ξ² as an upper bound; token counts are anchored to the ~20B figure and scale linearly if that differs.
Usage
Custom architecture β load with trust_remote_code=True (the modeling code ships in this
repo via auto_map):
from transformers import AutoModelForCausalLM
model = AutoModelForCausalLM.from_pretrained(
"Quazim0t0/Escarda-86M-Base", trust_remote_code=True)
The tokenizer is the custom SpikeTokenizer (tokenizer.json, algorithm: length-max);
load it with the spike_tokenizer.py helper from the project rather than AutoTokenizer.
Acknowledgements
Built with Modal credits during the Small Models, Big Adventures Hackathon, and released to the community as a base to build on.
Citation
If you use this model, please cite:
@misc{escarda86mbase,
title = {Escarda-86M-Base: A ~86M-parameter SpikeWhaleLM},
author = {Dean Byrne (Quazim0t0)},
year = {2026},
howpublished = {HuggingFace, \url{https://huggingface.co/Quazim0t0/Escarda-86M-Base}},
note = {Quazim0t0/Escarda-86M-Base}
}
Escarda vs Byrne β vision family comparison
The Byrne family uses HRM refinement. Escarda = Byrne + JEPA (Joint-Embedding Predictive head) added alongside HRM in both the vision encoder and the LM trunk β auxiliary only, zero inference cost.
Vision encoder (DINOv2 teacher-alignment, n=1024 held-out):
| Byrne-VE | Escarda-VE | |
|---|---|---|
| Params | 39.34M | 39.60M (+JEPA head) |
| CLS cosine | 0.776 | 0.771 |
| PATCH cosine | 0.600 | 0.584 |
| JEPA self-consistency | β | 0.040 |
Docling (same held-out doc images, atomic DocTags): both emit well-formed DocTags;
Byrne-Docling is marginally more complete on the hardest samples (closes </formula>,
includes the <code> wrapper), consistent with its slightly higher teacher-alignment.
Escarda-Docling is structurally on par and adds the JEPA representation-learning trait.
Pros/cons. Byrne (HRM): higher teacher-alignment, all capacity on distillation fidelity; no self-supervised objective. Escarda (HRM+JEPA): self-supervised neighbour-prediction (richer spatial structure) at zero inference cost, trading ~1β3% teacher-alignment. Same size class.
Family repos: Byrne-VE Β· Escarda-VE Β· Byrne-Docling-131M Β· Escarda-Docling-126M
Update: engram repair (behavior-preserving)
The n-gram Engram memory in the original weights was degenerate: with the frozen LSH compressor at init scale, every token hashed to bucket 0, so only one table row ever received gradient. This revision rescales the (frozen) compressor and broadcasts the learned bucket-0 vector across all table rows.
Outputs are bit-identical to the previous revision (verified: max logit difference 0.0 across a prompt battery). The only change: the Engram's hash now spreads across the full table and every bucket is independently trainable β so if you distill or SFT on top of this base, the n-gram memory will actually learn instead of staying a constant bias.
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