- repeat_kv CUDA kernel: fwd head-block gather, bwd DETERMINISTIC group-sum (each
kv head sums its group of query-head grads; no atomics) + Tensor/ops node.
- Config gains num_kv_heads (default = n_heads → MHA); wk/wv project to kv_dim;
attention() repeat_kv-broadcasts K/V to nh heads before the UNCHANGED composed
& flash SDPA → GQA on both paths. group=1 is identity → MHA bit-identical.
- --kv-heads flag on train/train_ddp/export_safetensors/greedy_sample; export
writes real num_key_value_heads (xserv repeat_kv grouping aligned).
- Tests: repeat_kv grad-check (group>1 grad-sum + group=1 identity); model gqa.rs
(GQA flash==composed fp32/bf16, group=1 bit-identical to MHA, kv-proj shape);
parity_dump+parity.py GQA path (repeat_interleave) via XTRAIN_PARITY_KV_HEADS.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
Add flash_plus_dropout_grad_check_fp32 to xtrain-model dropout tests: the two
orthogonal Phase-2 features (T14 flash-attn, T18 dropout) in the same model must
still grad-check. Both models run train-mode p=0.2 (identical masks, seed is
flash-independent) so the only delta is the SDPA reduction order — checked against
the flash-vs-composed tolerance.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
Config.dropout (default 0). TinyTransformer gets a Cell<bool> training switch
(train()/eval()/with_training, default eval = safe) + a Cell<u64> step_seed bumped
once per training forward. forward_batched derives a per-layer block_seed (pure fn
of step_seed×layer) and block_forward derives two per-site seeds, inserting
ops::dropout at the attn and ffn sub-block outputs (before each residual). The
seed is a pure function of (step_seed, layer, site) so the checkpoint (T13)
recompute re-derives the same masks → grads stay exact. p=0 or eval → no dropout
node → graph bit-identical to pre-T18.
train_loop: model.train() per step (restored after eval flips to eval); eval_loss
runs model.eval(). bin/train: --dropout flag → cfg.dropout. Export/sampling run in
eval (default), so exported weights are dropout-free (xserv closed loop unaffected).
Model-level tests (dropout.rs): p=0 bit-identical to no-dropout (logits/loss/grads);
eval(p>0) == p=0 identity; train differs from eval + finite; recompute-with-dropout
grads match non-recompute (fp32 + bf16).
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
autograd: flash_attention_batched_bwd (dQ/dK/dV finite-diff, seq>tile)
+ flash_matches_composed_fwd. model/tests/flash.rs: flash==composed
on-vs-off (logits/loss/every param grad), fp32 + bf16. parity_dump:
XTRAIN_PARITY_FLASH dumps the flash path for the same parity.py oracle
(PyTorch SDPA parity at B>1). train + train_ddp get the --flash flag.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
Design doc for per-block gradient checkpointing (KI-3): the no-tape forward +
recompute-on-backward design, the `checkpoint` primitive, per-block wrapping,
the exactness/correctness argument (same kernels + inputs → identical grads),
composition with bf16+DDP+batched, and the verification plan (on-vs-off grad
gate + memory/throughput before→after, dim1024-fits). Bench table left as TBD
to fill after the dash5 run.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
Wrap each transformer block's forward in the checkpoint primitive when
recompute is enabled (Phase T13 / KI-3). To make the block forward a pure
segment fn (no `&self` borrow, so it can re-run in the backward closure),
extract the block body + its helpers (linear / norm_gamma / attention /
swiglu_mlp) into free functions parameterised by (cfg, compute_dtype) and add
`Block::block_params()` (the 11 leaves in the params() per-block order). The
non-recompute path calls `block_forward` directly — identical graph to before.
- `TinyTransformer::with_recompute(bool)` builder (opt-in; default off keeps the
unchanged tape / bit-identical numerics).
- `--recompute` flag wired into bin/train and bin/train_ddp (DDP: each rank
checkpoints independently).
Correctness gate: tests/recompute.rs builds two identical models (recompute
on/off), runs the same batched loss+backward, and asserts the forward logits,
the loss, and EVERY parameter grad match within tight fp tol — parameterised
over fp32 and bf16 (T12 composition).
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
The `keep bf16 logits` change made forward_batched return bf16 logits
in bf16 mode; the bf16 test's host read must cast to f32 first.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
- TinyTransformer::with_compute_dtype(BF16): embedding stays fp32
master then casts to bf16; each linear casts its fp32 weight to bf16
on the fly; logits cast back to fp32 for cross-entropy. Default F32
reproduces the v0-v4 forward graph bit-for-bit.
- --bf16 flag on bin/train and bin/train_ddp (off by default).
- tests/bf16.rs: same fp32 master weights run fp32 vs bf16; assert
loss/logits/grads within a loose bf16 tol, no NaN, and grads are
fp32 (master untouched).
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
forward_batched(ids[B*S], batch)/loss_batched: run B equal-length sequences as
ONE forward over flattened [B*S] ids, so every linear is one big [B*S,dim] GEMM.
Attention reshapes to [B*nh,S,hd], runs the fused batched causal SDPA (per-seq
mask + RoPE period=S, no cross-sequence attention), writes back [B*S,dim]. The
old per-(batch,head) loop + host-round-tripping split/merge_heads + the additive
causal_mask leaf are gone. forward(ids[seq]) is now forward_batched(ids,1), so
the sampler / inference path (batch=1) is unchanged.
+batched_ids_tensor helper. New batched.rs test: batched forward == looped
single-sequence (logits identical 0.0, grads 6.4e-4, loss identical). PyTorch
parity now exercises B>1 (B=2,S=4): loss 5e-8, logits 6.9e-6, all 25 param
grads within rtol — verifying per-seq RoPE position + per-seq causal masking.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
xserv's Qwen3 forward unconditionally applies per-head RMSNorm to Q and K
(q_norm/k_norm, shape [head_dim]) before RoPE — even gamma=1 is a real RMS
divide, not identity. xtrain never had this, so an exact xserv<->xtrain loop
was structurally impossible. Add it (reusing the 2D rms_norm op on the
[seq*nh, hd] head rows, inserted between reshape and rope to mirror
qwen3.rs's order) so the trained model is genuinely Qwen3-compatible.
params() inserts q_norm,k_norm after wv; num_params() counts them; the
PyTorch parity refs (parity.py / adamw_parity.py) + their name lists add the
same step so the dumps stay self-consistent.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
parity_dump.rs (#[ignore] fixture generator) dumps the model's exact
weights, ids, forward logits, loss, and per-param grads after one
backward. parity.py rebuilds the IDENTICAL model in PyTorch (same x@W
convention, RoPE rotate_half pos=row, RMSNorm, SwiGLU, causal SDPA),
runs fwd+bwd, and compares logits + every grad within rtol.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>