Add DynamicSimilaritySampler — embedding-kNN batches with mutex constraint

Batches assembled from visually-similar drone queries pressure the model to
learn finer discriminative features. Random mutex batches average ~0.26
pairwise cosine similarity in query embedding space; DSS batches average
~0.71 — confirming the lookalikes grouping works as intended.

Algorithm per batch:
  1. Pick a random seed drone from the remaining pool.
  2. Rank the entire remaining pool by cosine similarity to the seed.
  3. Walk the ranking in descending order; add items whose sat_candidates
     don't collide with the batch's already-claimed set.
  4. Drop the seed if no valid batch can be assembled (rare mutex deadlock).

Inherits MutuallyExclusiveSampler semantics — no false negatives. Degrades
gracefully to mutex-only when no embeddings are set (warmup epochs, or if
`sampler_type="mutex"` is chosen).

Integration in `train_gtauav.py`:
  - New `_embed_drone_queries` helper: model.encode_query forwarded over
    GTAUAVDroneQuery, returns [N, D] CPU tensor. ~13s per 1024 queries on
    a 4090 → ~5 min for the full 25K train set.
  - Epoch loop re-embeds every `dss_reembed_every` epochs after a `dss_warmup_epochs`
    warmup (first epochs use mutex-only since untrained embeddings aren't
    informative for kNN).
  - Config: `sampler_type` ∈ {"mutex", "dss"}. Default flipped to "dss".

Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
This commit is contained in:
pikaliov
2026-04-24 16:12:34 +03:00
parent c30726998b
commit f8e0631210
5 changed files with 391 additions and 14 deletions

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from __future__ import annotations
"""Dynamic Similarity Sampler — hard batch construction via embedding kNN.
Builds on MutuallyExclusiveSampler: keeps the no-false-negatives guarantee
(disjoint `sat_candidates` within a batch), but additionally pressures the
model by packing visually-similar drone queries together. The intuition is
that in-batch negatives which are easy to distinguish contribute little
gradient — if the batch contains lookalikes, the model has to learn finer
features.
Workflow:
1. Training loop calls `update_embeddings(query_embeddings)` at the start
of each epoch (or every N epochs) with current query embeddings.
2. `_generate_batches` picks a random seed drone, ranks the rest by cosine
similarity to the seed, then greedily packs highest-similarity drones
whose `sat_candidates` don't conflict.
3. If no embeddings are set yet, falls back to mutex-only behavior (first
epoch, or warmup before the model has useful representations).
"""
import logging
import random
from typing import Iterator, Sequence
import torch
import torch.nn.functional as F
from torch.utils.data.sampler import Sampler
LOGGER = logging.getLogger("caption_test.dss_sampler")
class DynamicSimilaritySampler(Sampler[list[int]]):
"""Batch sampler: visually-similar drones packed per batch, mutex-preserved.
Args:
sat_candidates_per_item: Valid satellite names per dataset index
(positive + semi-positive).
batch_size: Target batch size. Partial trailing batches are dropped.
shuffle: Randomize seed ordering each epoch.
seed: Base RNG seed (effective seed is `seed + epoch`).
allow_partial: Yield trailing partial batch if non-empty.
"""
def __init__(
self,
sat_candidates_per_item: Sequence[Sequence[str]],
batch_size: int,
shuffle: bool = True,
seed: int = 0,
allow_partial: bool = False,
) -> None:
if batch_size <= 0:
raise ValueError(f"batch_size must be positive, got {batch_size}")
self._item_sats: list[frozenset[str]] = [
frozenset(s) for s in sat_candidates_per_item
]
self.batch_size = batch_size
self.shuffle = shuffle
self.seed = seed
self.allow_partial = allow_partial
self.epoch = 0
self._embeddings: torch.Tensor | None = None
self._cached_len: int | None = None
def set_epoch(self, epoch: int) -> None:
self.epoch = epoch
self._cached_len = None
def update_embeddings(self, embeddings: torch.Tensor) -> None:
"""Store query embeddings [N, D] for the next epoch's sampling.
Call from the training loop before starting each epoch where you want
DSS to be active. Stored on CPU as float32 and L2-normalized.
"""
if embeddings.size(0) != len(self._item_sats):
raise ValueError(
f"embeddings have {embeddings.size(0)} rows but sampler tracks "
f"{len(self._item_sats)} items",
)
self._embeddings = F.normalize(embeddings.detach().cpu().float(), dim=-1)
self._cached_len = None
LOGGER.info(
"DSS embeddings updated: %d × %d", *self._embeddings.shape,
)
def clear_embeddings(self) -> None:
"""Revert to mutex-only sampling for the next epoch."""
self._embeddings = None
self._cached_len = None
def _generate_batches_mutex_only(self) -> list[list[int]]:
"""Fallback: greedy mutex packing without similarity ranking."""
rng = random.Random(self.seed + self.epoch) if self.shuffle else None
remaining = list(range(len(self._item_sats)))
if rng is not None:
rng.shuffle(remaining)
batches: list[list[int]] = []
while remaining:
batch: list[int] = []
claimed: set[str] = set()
next_remaining: list[int] = []
for idx in remaining:
sats = self._item_sats[idx]
if len(batch) < self.batch_size and not (sats & claimed):
batch.append(idx)
claimed |= sats
else:
next_remaining.append(idx)
if len(batch) == self.batch_size:
batches.append(batch)
elif self.allow_partial and batch:
batches.append(batch)
break
else:
break
remaining = next_remaining
if rng is not None:
rng.shuffle(remaining)
return batches
def _generate_batches_dss(self) -> list[list[int]]:
"""Similarity-guided batches using stored embeddings."""
assert self._embeddings is not None
rng = random.Random(self.seed + self.epoch) if self.shuffle else None
emb = self._embeddings # already L2-normalized, on CPU
n = emb.size(0)
remaining = set(range(n))
batches: list[list[int]] = []
while len(remaining) >= self.batch_size:
seed_idx = (
rng.choice(list(remaining))
if rng is not None
else next(iter(remaining))
)
# Cosine similarity from seed to all items (fp32 matmul, ~25K ops).
sims = emb @ emb[seed_idx] # [N]
order = sims.argsort(descending=True).tolist()
batch: list[int] = []
claimed: set[str] = set()
for idx in order:
if idx not in remaining:
continue
sats = self._item_sats[idx]
if sats & claimed:
continue
batch.append(idx)
claimed |= sats
if len(batch) == self.batch_size:
break
if len(batch) < self.batch_size:
# Couldn't fill from this seed's neighborhood (heavy mutex
# conflict). Drop the seed and retry with remaining pool.
remaining.discard(seed_idx)
continue
batches.append(batch)
for i in batch:
remaining.discard(i)
if self.allow_partial and remaining:
# Mutex-pack whatever's left.
claimed = set()
tail: list[int] = []
for idx in remaining:
sats = self._item_sats[idx]
if not (sats & claimed):
tail.append(idx)
claimed |= sats
if tail:
batches.append(tail)
return batches
def _generate_batches(self) -> list[list[int]]:
if self._embeddings is None:
return self._generate_batches_mutex_only()
return self._generate_batches_dss()
def __iter__(self) -> Iterator[list[int]]:
batches = self._generate_batches()
self._cached_len = len(batches)
for batch in batches:
yield batch
def __len__(self) -> int:
if self._cached_len is None:
self._cached_len = len(self._generate_batches())
return self._cached_len