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Lodestone-Tagger-UI / inference_tagger_standalone.py
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Add image similarity mode using forward_embedding FEATURE_DIM descriptors
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"""DINOv3 ViT-H/16+ Tagger — Fully Standalone Inference Script
Zero dependency on transformers, trainer code, or any internal module.
Only requires: torch, torchvision, safetensors, Pillow, requests.
 pip install torch torchvision safetensors Pillow requests
The DINOv3 ViT-H/16+ architecture is implemented directly here, with weights
loaded from a .safetensors checkpoint. The state-dict key names match the
HuggingFace transformers layout exactly so checkpoints are interchangeable.
Usage
-----
# Single image, top-30 tags:
python inference_tagger_standalone.py \
 --checkpoint tagger_checkpoints/2026-03-28_22-57-47.safetensors \
 --vocab tagger_vocab.json \
 --images photo.jpg \
 --topk 30
# URL input:
python inference_tagger_standalone.py \
 --checkpoint tagger_checkpoints/2026-03-28_22-57-47.safetensors \
 --vocab tagger_vocab.json \
 --images https://example.com/photo.jpg
# Threshold instead of top-k:
python inference_tagger_standalone.py ... --threshold 0.4
# Pipe-friendly comma-separated tags (one line per image):
python inference_tagger_standalone.py ... --format tags
# JSON output:
python inference_tagger_standalone.py ... --format json
Output formats (--format)
-------------------------
 pretty (default) — human-readable table with scores
 tags — comma-separated tag string, one line per image
 json — JSON array of {file, tags: [{tag, score}]} objects
"""
from __future__ import annotations
import argparse
import json
import math
import sys
from functools import lru_cache
from io import BytesIO
from pathlib import Path
import requests
import torch
import torch.nn as nn
import torch.nn.functional as F
import torchvision.transforms.v2 as v2
from PIL import Image
from safetensors.torch import load_file
# =============================================================================
# DINOv3 ViT-H/16+ — hardcoded architecture
# All hyperparameters match facebook/dinov3-vith16plus-pretrain-lvd1689m
# =============================================================================
D_MODEL = 1280
N_HEADS = 20
HEAD_DIM = D_MODEL // N_HEADS # 64
N_LAYERS = 32
D_FFN = 5120
N_REGISTERS = 4
PATCH_SIZE = 16
ROPE_THETA = 100.0
ROPE_RESCALE = 2.0
LN_EPS = 1e-5
LAYERSCALE = 1.0
FEATURE_DIM = (1 + N_REGISTERS) * D_MODEL # 6400
# ---------------------------------------------------------------------------
# RoPE helpers
# ---------------------------------------------------------------------------
@lru_cache(maxsize=32)
def _patch_coords_cached(h: int, w: int, device_str: str) -> torch.Tensor:
 device = torch.device(device_str)
 cy = torch.arange(0.5, h, dtype=torch.float32, device=device) / h
 cx = torch.arange(0.5, w, dtype=torch.float32, device=device) / w
 coords = torch.stack(torch.meshgrid(cy, cx, indexing="ij"), dim=-1).flatten(0, 1)
 coords = 2.0 * coords - 1.0
 coords = coords * ROPE_RESCALE
 return coords # [h*w, 2]
def _build_rope(
 h_patches: int, w_patches: int, dtype: torch.dtype, device: torch.device
):
 coords = _patch_coords_cached(h_patches, w_patches, str(device))
 inv_freq = 1.0 / (
 ROPE_THETA
 ** torch.arange(0, 1, 4 / HEAD_DIM, dtype=torch.float32, device=device)
 )
 angles = 2 * math.pi * coords[:, :, None] * inv_freq[None, None, :]
 angles = angles.flatten(1, 2).tile(2)
 cos = torch.cos(angles).to(dtype).unsqueeze(0).unsqueeze(0)
 sin = torch.sin(angles).to(dtype).unsqueeze(0).unsqueeze(0)
 return cos, sin
def _rotate_half(x: torch.Tensor) -> torch.Tensor:
 h = x.shape[-1] // 2
 return torch.cat((-x[..., h:], x[..., :h]), dim=-1)
def _apply_rope(q: torch.Tensor, k: torch.Tensor, cos: torch.Tensor, sin: torch.Tensor):
 n_pre = 1 + N_REGISTERS
 q_pre, q_pat = q[..., :n_pre, :], q[..., n_pre:, :]
 k_pre, k_pat = k[..., :n_pre, :], k[..., n_pre:, :]
 q_pat = q_pat * cos + _rotate_half(q_pat) * sin
 k_pat = k_pat * cos + _rotate_half(k_pat) * sin
 return torch.cat([q_pre, q_pat], dim=-2), torch.cat([k_pre, k_pat], dim=-2)
# ---------------------------------------------------------------------------
# Transformer blocks
# ---------------------------------------------------------------------------
class _Attention(nn.Module):
 def __init__(self):
 super().__init__()
 self.q_proj = nn.Linear(D_MODEL, D_MODEL, bias=True)
 self.k_proj = nn.Linear(D_MODEL, D_MODEL, bias=False)
 self.v_proj = nn.Linear(D_MODEL, D_MODEL, bias=True)
 self.o_proj = nn.Linear(D_MODEL, D_MODEL, bias=True)
def forward(self, x, cos, sin):
 B, S, _ = x.shape
 q = self.q_proj(x).view(B, S, N_HEADS, HEAD_DIM).transpose(1, 2)
 k = self.k_proj(x).view(B, S, N_HEADS, HEAD_DIM).transpose(1, 2)
 v = self.v_proj(x).view(B, S, N_HEADS, HEAD_DIM).transpose(1, 2)
 q, k = _apply_rope(q, k, cos, sin)
 out = F.scaled_dot_product_attention(q, k, v, scale=HEAD_DIM**-0.5)
 return self.o_proj(out.transpose(1, 2).reshape(B, S, D_MODEL))
class _GatedMLP(nn.Module):
 def __init__(self):
 super().__init__()
 self.gate_proj = nn.Linear(D_MODEL, D_FFN, bias=True)
 self.up_proj = nn.Linear(D_MODEL, D_FFN, bias=True)
 self.down_proj = nn.Linear(D_FFN, D_MODEL, bias=True)
def forward(self, x):
 return self.down_proj(F.silu(self.gate_proj(x)) * self.up_proj(x))
class _Block(nn.Module):
 def __init__(self):
 super().__init__()
 self.norm1 = nn.LayerNorm(D_MODEL, eps=LN_EPS)
 self.attention = _Attention()
 self.layer_scale1 = nn.Parameter(torch.full((D_MODEL,), LAYERSCALE))
 self.norm2 = nn.LayerNorm(D_MODEL, eps=LN_EPS)
 self.mlp = _GatedMLP()
 self.layer_scale2 = nn.Parameter(torch.full((D_MODEL,), LAYERSCALE))
def forward(self, x, cos, sin):
 x = x + self.attention(self.norm1(x), cos, sin) * self.layer_scale1
 x = x + self.mlp(self.norm2(x)) * self.layer_scale2
 return x
class _Embeddings(nn.Module):
 def __init__(self):
 super().__init__()
 # zeros() rather than empty() so a forgotten checkpoint key fails
 # predictably instead of producing undefined outputs.
 self.cls_token = nn.Parameter(torch.zeros(1, 1, D_MODEL))
 self.mask_token = nn.Parameter(torch.zeros(1, 1, D_MODEL))
 self.register_tokens = nn.Parameter(torch.zeros(1, N_REGISTERS, D_MODEL))
 self.patch_embeddings = nn.Conv2d(
 3, D_MODEL, kernel_size=PATCH_SIZE, stride=PATCH_SIZE
 )
def forward(self, pixel_values):
 B = pixel_values.shape[0]
 dtype = self.patch_embeddings.weight.dtype
 patches = (
 self.patch_embeddings(pixel_values.to(dtype)).flatten(2).transpose(1, 2)
 )
 cls = self.cls_token.expand(B, -1, -1)
 regs = self.register_tokens.expand(B, -1, -1)
 return torch.cat([cls, regs, patches], dim=1)
class DINOv3ViTH(nn.Module):
 """DINOv3 ViT-H/16+ backbone.
 Token layout: [CLS, reg_0..reg_3, patch_0..patch_N].
 Returns last_hidden_state [B, 1+R+P, D_MODEL].
 """
def __init__(self):
 super().__init__()
 self.embeddings = _Embeddings()
 self.layer = nn.ModuleList([_Block() for _ in range(N_LAYERS)])
 self.norm = nn.LayerNorm(D_MODEL, eps=LN_EPS)
def forward(self, pixel_values):
 _, _, H, W = pixel_values.shape
 x = self.embeddings(pixel_values)
 h_p, w_p = H // PATCH_SIZE, W // PATCH_SIZE
 cos, sin = _build_rope(h_p, w_p, x.dtype, pixel_values.device)
 for block in self.layer:
 x = block(x, cos, sin)
 return self.norm(x)
def get_image_tokens(self, pixel_values):
 """Return patch tokens only (no CLS/registers) as [B, h_p*w_p, D_MODEL]
 and the spatial grid dimensions (h_p, w_p)."""
 _, _, H, W = pixel_values.shape
 h_p, w_p = H // PATCH_SIZE, W // PATCH_SIZE
 x = self.embeddings(pixel_values)
 cos, sin = _build_rope(h_p, w_p, x.dtype, pixel_values.device)
 for block in self.layer:
 x = block(x, cos, sin)
 x = self.norm(x)
 # token layout: [CLS, reg_0..reg_R-1, patch_0..patch_N]
 patch_tokens = x[:, 1 + N_REGISTERS :, :] # [B, h_p*w_p, D_MODEL]
 return patch_tokens, h_p, w_p
# =============================================================================
# Head — auto-detected from the checkpoint
# =============================================================================
class _LowRankHead(nn.Module):
 """Two-matrix low-rank projection head.
 features (in_dim)
 → Linear(in_dim, rank, bias=?)
 → Linear(rank, num_tags, bias=?)
 """
def __init__(
 self, in_dim: int, rank: int, num_tags: int, down_bias: bool, up_bias: bool
 ):
 super().__init__()
 self.proj_down = nn.Linear(in_dim, rank, bias=down_bias)
 self.proj_up = nn.Linear(rank, num_tags, bias=up_bias)
def forward(self, x):
 return self.proj_up(self.proj_down(x))
def _build_head_from_checkpoint(
 head_sd: dict,
 in_dim: int,
 num_tags: int,
) -> tuple[nn.Module, dict]:
 """Inspect head_sd and build a matching Module.
 Supports two layouts, in order of preference:
 1. Single linear — any ``*.weight`` with shape [num_tags, in_dim]
 2. Low-rank pair (2 mats) — one ``*.weight`` [rank, in_dim] plus
 one ``*.weight`` [num_tags, rank]
 Returns (module, remapped_state_dict) where the remapped state dict
 matches the module's own key names so strict loading works.
 """
 weights_2d = [
 (k, v) for k, v in head_sd.items() if k.endswith(".weight") and v.ndim == 2
 ]
# --- Case 1: single dense linear ---------------------------------------
 singles = [(k, v) for k, v in weights_2d if tuple(v.shape) == (num_tags, in_dim)]
 if len(weights_2d) <= 2 and len(singles) == 1:
 wkey, wval = singles[0]
 base = wkey[: -len(".weight")]
 bias_key = base + ".bias"
 has_bias = bias_key in head_sd
 module = nn.Linear(in_dim, num_tags, bias=has_bias)
 remapped = {"weight": wval}
 if has_bias:
 remapped["bias"] = head_sd[bias_key]
 # Sanity check: no extra keys we don't understand
 expected_src = {wkey} | ({bias_key} if has_bias else set())
 extra = set(head_sd) - expected_src
 if extra:
 raise RuntimeError(
 f"Head has single-linear shape but extra unknown keys: {sorted(extra)}"
 )
 return module, remapped
# --- Case 2: low-rank pair ---------------------------------------------
 down = None # (key, tensor) with shape [rank, in_dim]
 up = None # (key, tensor) with shape [num_tags, rank]
 for k, v in weights_2d:
 if v.shape[1] == in_dim and v.shape[0] != num_tags:
 down = (k, v)
 elif v.shape[0] == num_tags and v.shape[1] != in_dim:
 up = (k, v)
if down is not None and up is not None:
 rank_down = down[1].shape[0]
 rank_up = up[1].shape[1]
 if rank_down != rank_up:
 raise RuntimeError(
 f"Low-rank head: inner dims disagree "
 f"(down out={rank_down}, up in={rank_up})"
 )
down_key, down_w = down
 up_key, up_w = up
 down_base = down_key[: -len(".weight")]
 up_base = up_key[: -len(".weight")]
 down_bias_key = down_base + ".bias"
 up_bias_key = up_base + ".bias"
 has_down_bias = down_bias_key in head_sd
 has_up_bias = up_bias_key in head_sd
module = _LowRankHead(
 in_dim=in_dim,
 rank=rank_down,
 num_tags=num_tags,
 down_bias=has_down_bias,
 up_bias=has_up_bias,
 )
 remapped = {
 "proj_down.weight": down_w,
 "proj_up.weight": up_w,
 }
 if has_down_bias:
 remapped["proj_down.bias"] = head_sd[down_bias_key]
 if has_up_bias:
 remapped["proj_up.bias"] = head_sd[up_bias_key]
# Sanity check
 expected_src = {down_key, up_key}
 if has_down_bias:
 expected_src.add(down_bias_key)
 if has_up_bias:
 expected_src.add(up_bias_key)
 extra = set(head_sd) - expected_src
 if extra:
 raise RuntimeError(
 f"Low-rank head detected but checkpoint has extra unknown "
 f"head keys: {sorted(extra)}"
 )
print(
 f"[Tagger] Detected low-rank head: "
 f"in_dim={in_dim}, rank={rank_down}, num_tags={num_tags} "
 f"(down_bias={has_down_bias}, up_bias={has_up_bias})"
 )
 return module, remapped
raise RuntimeError(
 "Could not infer head architecture from checkpoint. "
 f"Non-backbone keys found: {sorted(head_sd.keys())}"
 )
# =============================================================================
# Tagger wrapper module
# =============================================================================
class DINOv3Tagger(nn.Module):
 """Backbone + head. The head is attached after the checkpoint is
 inspected (so we can build the right shape)."""
def __init__(self):
 super().__init__()
 self.backbone = DINOv3ViTH()
 self.head: nn.Module | None = None # attached by Tagger
def forward(self, pixel_values):
 hidden = self.backbone(pixel_values)
 cls = hidden[:, 0, :]
 regs = hidden[:, 1 : 1 + N_REGISTERS, :].flatten(1)
 features = torch.cat([cls, regs], dim=-1).float() # fp32 for head
 return self.head(features)
def forward_embedding(self, pixel_values):
 """Return the FEATURE_DIM=6400 image descriptor without applying the head.
 Same as forward() but stops before self.head — use this for similarity queries.
 """
 hidden = self.backbone(pixel_values)
 cls = hidden[:, 0, :]
 regs = hidden[:, 1 : 1 + N_REGISTERS, :].flatten(1)
 features = torch.cat([cls, regs], dim=-1).float() # fp32 for head
 return features
# =============================================================================
# Checkpoint loading helpers
# =============================================================================
def _split_and_clean_state_dict(sd: dict) -> tuple[dict, dict]:
 """Split full state dict into (backbone_sd, head_sd), stripping the
 ``backbone.`` prefix and applying the remaps needed to match
 ``DINOv3ViTH``'s parameter layout:
 1. ``backbone.model.layer.N.*`` → ``layer.N.*``
 (the checkpoint has an HF-style intermediate ``model`` wrapper
 that our flat backbone class does not)
 2. ``...layer_scale{1,2}.lambda1`` → ``...layer_scale{1,2}``
 (HF stores layer_scale as a sub-module with a ``lambda1``
 parameter; we use a plain ``nn.Parameter``)
 3. Drop any ``rope_embeddings`` buffers (recomputed on the fly)
 """
 backbone_sd: dict = {}
 head_sd: dict = {}
 for k, v in sd.items():
 if k.startswith("backbone."):
 nk = k[len("backbone.") :]
 # Remap (1): strip intermediate "model." before "layer."
 if nk.startswith("model.layer."):
 nk = nk[len("model.") :]
 backbone_sd[nk] = v
 else:
 head_sd[k] = v
# Remap (2): layer.N.layer_scale{1,2}.lambda1 → layer.N.layer_scale{1,2}
 for k in list(backbone_sd.keys()):
 if ".layer_scale" in k and k.endswith(".lambda1"):
 backbone_sd[k[: -len(".lambda1")]] = backbone_sd.pop(k)
# Remap (3): drop rope buffers (recomputed on the fly)
 for k in list(backbone_sd.keys()):
 if "rope_embeddings" in k:
 backbone_sd.pop(k)
return backbone_sd, head_sd
# =============================================================================
# Image preprocessing
# =============================================================================
_IMAGENET_MEAN = [0.485, 0.456, 0.406]
_IMAGENET_STD = [0.229, 0.224, 0.225]
def _snap(x: int, m: int) -> int:
 return max(m, (x // m) * m)
def _open_image(source) -> Image.Image:
 s = str(source)
 if s.startswith("http://") or s.startswith("https://"):
 r = requests.get(s, timeout=30)
 r.raise_for_status()
 return Image.open(BytesIO(r.content)).convert("RGB")
 return Image.open(source).convert("RGB")
def preprocess_image(source, max_size: int = 1024) -> torch.Tensor:
 """Load and preprocess an image → [1, 3, H, W] float32, ImageNet-normalised.
 Aspect ratio is preserved: a single scale factor is chosen so that the
 long edge fits inside max_size after snapping to a PATCH_SIZE multiple.
 """
 img = _open_image(source)
 w, h = img.size
# Target long-edge (snapped to patch multiple).
 long_edge = max(w, h)
 target_long = _snap(min(long_edge, max_size), PATCH_SIZE)
 scale = target_long / long_edge
new_w = _snap(max(PATCH_SIZE, round(w * scale)), PATCH_SIZE)
 new_h = _snap(max(PATCH_SIZE, round(h * scale)), PATCH_SIZE)
return v2.Compose(
 [
 v2.Resize((new_h, new_w), interpolation=v2.InterpolationMode.LANCZOS),
 v2.ToImage(),
 v2.ToDtype(torch.float32, scale=True),
 v2.Normalize(mean=_IMAGENET_MEAN, std=_IMAGENET_STD),
 ]
 )(img).unsqueeze(0)
# =============================================================================
# Tagger wrapper
# =============================================================================
class Tagger:
 """Inference wrapper for DINOv3Tagger (ViT-H/16+).
 Parameters
 ----------
 checkpoint_path : str
 Path to a .safetensors or .pt/.pth checkpoint.
 vocab_path : str
 Path to tagger_vocab.json or tagger_vocab_with_categories.json
 (either must contain an ``idx2tag`` list).
 device : str
 "cuda", "cuda:0", "cpu", ...
 dtype : torch.dtype
 Backbone precision. bfloat16 recommended on Ampere+, float16 for
 older GPUs, float32 for CPU. The head always runs in fp32.
 max_size : int
 Long-edge cap in pixels before feeding to the model.
 """
def __init__(
 self,
 checkpoint_path: str,
 vocab_path: str,
 device: str = "cuda",
 dtype: torch.dtype = torch.bfloat16,
 max_size: int = 1024,
 ):
 want_cuda = device.startswith("cuda")
 if want_cuda and not torch.cuda.is_available():
 print("[Tagger] CUDA not available, falling back to CPU")
 device = "cpu"
 dtype = torch.float32
 self.device = torch.device(device)
 self.dtype = dtype
 self.max_size = max_size
with open(vocab_path) as f:
 data = json.load(f)
 self.idx2tag: list[str] = data["idx2tag"]
 self.num_tags = len(self.idx2tag)
 print(f"[Tagger] Vocabulary: {self.num_tags:,} tags")
# --- Load checkpoint to CPU first so we can inspect shapes ---------
 print(f"[Tagger] Loading checkpoint: {checkpoint_path}")
 if checkpoint_path.endswith((".safetensors", ".sft")):
 sd = load_file(checkpoint_path, device="cpu")
 else:
 sd = torch.load(checkpoint_path, map_location="cpu")
backbone_sd, head_sd = _split_and_clean_state_dict(sd)
if not head_sd:
 raise RuntimeError(
 "Checkpoint contains no non-backbone keys — cannot build head."
 )
# --- Build model, inferring head shape from the checkpoint --------
 self.model = DINOv3Tagger()
 head_module, head_sd_remapped = _build_head_from_checkpoint(
 head_sd,
 in_dim=FEATURE_DIM,
 num_tags=self.num_tags,
 )
 self.model.head = head_module
# --- Strict load — mismatches raise instead of silently passing ----
 self.model.backbone.load_state_dict(backbone_sd, strict=True)
 self.model.head.load_state_dict(head_sd_remapped, strict=True)
# --- Move to device. Backbone → bf16/fp16; head stays fp32. --------
 self.model.backbone = self.model.backbone.to(device=self.device, dtype=dtype)
 self.model.head = self.model.head.to(device=self.device, dtype=torch.float32)
 self.model.eval()
 print(f"[Tagger] Ready on {self.device} (backbone={dtype}, head=fp32)")
@torch.no_grad()
 def embed_pca(
 self,
 image,
 n_components: int = 3,
 max_size: int | None = None,
 ) -> "Image.Image":
 """Run PCA on the patch-token features of *image* and return a
 false-colour RGB PIL image where R/G/B channels correspond to the
 first three principal components, each normalised to [0, 255].
 Parameters
 ----------
 image :
 Local path, URL, or PIL.Image.Image.
 n_components :
 Number of PCA components (must be 3 for RGB output).
 max_size :
 Long-edge cap in pixels (defaults to ``self.max_size``).
 """
 if n_components != 3:
 raise ValueError("n_components must be 3 for false-colour RGB output")
 if max_size is None:
 max_size = self.max_size
if isinstance(image, Image.Image):
 img = image.convert("RGB")
 w, h = img.size
 scale = min(1.0, max_size / max(w, h))
 new_w = _snap(round(w * scale), PATCH_SIZE)
 new_h = _snap(round(h * scale), PATCH_SIZE)
 pv = (
 v2.Compose(
 [
 v2.Resize(
 (new_h, new_w), interpolation=v2.InterpolationMode.LANCZOS
 ),
 v2.ToImage(),
 v2.ToDtype(torch.float32, scale=True),
 v2.Normalize(mean=_IMAGENET_MEAN, std=_IMAGENET_STD),
 ]
 )(img)
 .unsqueeze(0)
 .to(self.device)
 )
 else:
 pv = preprocess_image(image, max_size=max_size).to(self.device)
with torch.autocast(device_type=self.device.type, dtype=self.dtype):
 patch_tokens, h_p, w_p = self.model.backbone.get_image_tokens(pv)
# patch_tokens: [1, h_p*w_p, D_MODEL] → [N, D]
 tokens = patch_tokens[0].float() # fp32 for PCA
# Centre
 mean = tokens.mean(dim=0, keepdim=True)
 tokens_c = tokens - mean
# PCA via SVD (economy)
 _, _, Vt = torch.linalg.svd(tokens_c, full_matrices=False)
 components = Vt[:n_components] # [3, D]
 projected = tokens_c @ components.T # [N, 3]
# Normalise each component to [0, 1]
 lo = projected.min(dim=0).values
 hi = projected.max(dim=0).values
 projected = (projected - lo) / (hi - lo + 1e-8)
# Reshape to spatial grid and convert to uint8 PIL image
 rgb = projected.reshape(h_p, w_p, 3).cpu().numpy()
 rgb_uint8 = (rgb * 255).clip(0, 255).astype("uint8")
 return Image.fromarray(rgb_uint8, mode="RGB")
@torch.no_grad()
 def predict(
 self, image, topk: int | None = 30, threshold: float | None = None
 ) -> list[tuple[str, float]]:
 """Tag a single image (local path or URL)."""
 if topk is None and threshold is None:
 topk = 30
pv = preprocess_image(image, max_size=self.max_size).to(self.device)
 logits = self.model(pv)[0]
 scores = torch.sigmoid(logits.float())
if topk is not None:
 values, indices = scores.topk(min(topk, self.num_tags))
 else:
 assert threshold is not None
 indices = (scores >= threshold).nonzero(as_tuple=True)[0]
 values = scores[indices]
 order = values.argsort(descending=True)
 indices, values = indices[order], values[order]
return [
 (self.idx2tag[i], float(v))
 for i, v in zip(indices.tolist(), values.tolist())
 ]
@torch.no_grad()
 def predict_batch(
 self, images, topk: int | None = 30, threshold: float | None = None
 ):
 return [self.predict(img, topk=topk, threshold=threshold) for img in images]
# =============================================================================
# Output formatters
# =============================================================================
def _fmt_pretty(path: str, results) -> str:
 lines = [f"\n{'─' * 60}", f" {path}", f"{'─' * 60}"]
 for rank, (tag, score) in enumerate(results, 1):
 bar = "█" * int(score * 20)
 lines.append(f" {rank:>3}. {score:.3f} {bar:<20} {tag}")
 return "\n".join(lines)
def _fmt_tags(results) -> str:
 return ", ".join(tag for tag, _ in results)
def _fmt_json(path: str, results) -> dict:
 return {
 "file": path,
 "tags": [{"tag": t, "score": round(s, 4)} for t, s in results],
 }
# =============================================================================
# CLI
# =============================================================================
def main():
 parser = argparse.ArgumentParser(
 description="DINOv3 ViT-H/16+ tagger inference (standalone)",
 formatter_class=argparse.RawDescriptionHelpFormatter,
 )
 parser.add_argument(
 "--checkpoint", required=True, help="Path to .safetensors or .pt checkpoint"
 )
 parser.add_argument("--vocab", required=True, help="Path to tagger_vocab*.json")
 parser.add_argument(
 "--images", nargs="+", required=True, help="Image paths and/or http(s) URLs"
 )
 parser.add_argument(
 "--device", default="cuda", help="Device: cuda, cuda:0, cpu (default: cuda)"
 )
 parser.add_argument(
 "--max-size",
 type=int,
 default=1024,
 help="Long-edge cap in pixels (default: 1024)",
 )
mode = parser.add_mutually_exclusive_group()
 mode.add_argument(
 "--topk", type=int, default=30, help="Return top-k tags (default: 30)"
 )
 mode.add_argument(
 "--threshold", type=float, help="Return all tags with score >= threshold"
 )
parser.add_argument(
 "--format",
 choices=["pretty", "tags", "json"],
 default="pretty",
 help="Output format (default: pretty)",
 )
 args = parser.parse_args()
tagger = Tagger(
 checkpoint_path=args.checkpoint,
 vocab_path=args.vocab,
 device=args.device,
 max_size=args.max_size,
 )
topk, threshold = (None, args.threshold) if args.threshold else (args.topk, None)
 json_out = []
for src in args.images:
 is_url = str(src).startswith("http://") or str(src).startswith("https://")
 if not is_url and not Path(src).exists():
 print(f"[warning] File not found: {src}", file=sys.stderr)
 continue
 results = tagger.predict(src, topk=topk, threshold=threshold)
 if args.format == "pretty":
 print(_fmt_pretty(src, results))
 elif args.format == "tags":
 print(_fmt_tags(results))
 elif args.format == "json":
 json_out.append(_fmt_json(src, results))
if args.format == "json":
 print(json.dumps(json_out, indent=2, ensure_ascii=False))
if __name__ == "__main__":
 main()