chore: update README

chore: apply ruff rules
chore: update dependencies
2025-07-01 12:26:27 +00:00 · 2025-06-27 02:06:24 +08:00 · 2025-06-27 01:38:54 +08:00 · 2025-06-27 01:06:24 +08:00 · 2025-06-26 01:11:25 +08:00 · 2025-06-26 00:15:02 +08:00
55 changed files with 2107 additions and 723 deletions
--- a/.github/workflows/build-and-publish.yml
+++ b/.github/workflows/build-and-publish.yml
@ -0,0 +1,103 @@
 name: Build, Release, Publish
 on:
  workflow_dispatch:
  push:
    tags:
      - "*.*.*"
 jobs:
  build:
    name: Build package
    runs-on: ubuntu-latest
    steps:
      - name: Checkout
        uses: actions/checkout@v4
        with:
          fetch-depth: 0
      - name: Set up Python environment
        uses: actions/setup-python@v5
        with:
          python-version: "3.x"
      - name: Build package
        run: |
          pip install build
          python -m build
      - name: Store the distribution files
        uses: actions/upload-artifact@v4
        with:
          name: python-package-distributions
          path: dist/
  draft-release:
    name: Draft a release
    runs-on: ubuntu-latest
    needs:
      - build
    permissions:
      contents: write
      discussions: write
    steps:
      - name: Download the distribution files
        uses: actions/download-artifact@v4
        with:
          name: python-package-distributions
          path: dist/
      - name: Draft a release
        uses: softprops/action-gh-release@v2
        with:
          discussion_category_name: New releases
          draft: true
          generate_release_notes: true
          files: |
            dist/*
  publish-to-pypi:
    name: Publish distribution to PyPI
    runs-on: ubuntu-latest
    if: startsWith(github.ref, 'refs/tags/') # only publish to PyPI on tag pushes
    needs:
      - build
    environment:
      name: pypi
      url: https://pypi.org/p/arcaea-offline-ocr
    permissions:
      id-token: write
    steps:
      - name: Download the distribution files
        uses: actions/download-artifact@v4
        with:
          name: python-package-distributions
          path: dist/
      - name: Publish distribution to PyPI
        uses: pypa/gh-action-pypi-publish@release/v1
  publish-to-testpypi:
    name: Publish distribution to TestPyPI
    runs-on: ubuntu-latest
    needs:
      - build
    environment:
      name: testpypi
      url: https://test.pypi.org/p/arcaea-offline-ocr
    permissions:
      id-token: write
    steps:
      - name: Download the distribution files
        uses: actions/download-artifact@v4
        with:
          name: python-package-distributions
          path: dist/
      - name: Publish distribution to TestPyPI
        uses: pypa/gh-action-pypi-publish@release/v1
        with:
          repository-url: https://test.pypi.org/legacy/
--- a/.gitignore
+++ b/.gitignore
@ -1,6 +1,8 @@
 __debug*
 .vscode/
 *venv*/
 # Byte-compiled / optimized / DLL files
 __pycache__/
 *.py[cod]
--- a/.pre-commit-config.yaml
+++ b/.pre-commit-config.yaml
@ -4,13 +4,10 @@ repos:
    hooks:
      - id: end-of-file-fixer
      - id: trailing-whitespace
-  - repo: https://github.com/psf/black
+
-    rev: 23.1.0
+  - repo: https://github.com/astral-sh/ruff-pre-commit
    rev: v0.11.13
    hooks:
-      - id: black
+      - id: ruff
-        exclude: _builtin_templates.py
+        args: ["--fix"]
-  - repo: https://github.com/PyCQA/isort
+      - id: ruff-format
    rev: 5.12.0
    hooks:
      - id: isort
        exclude: _builtin_templates.py
--- a/675
+++ b/675
@ -0,0 +1,675 @@
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 of the GNU General Public License can be used, that proxy's public
 statement of acceptance of a version permanently authorizes you to
 choose that version for the Program.
 Later license versions may give you additional or different
 permissions. However, no additional obligations are imposed on any
 author or copyright holder as a result of your choosing to follow a
 later version.
 ### 15. Disclaimer of Warranty.
 THERE IS NO WARRANTY FOR THE PROGRAM, TO THE EXTENT PERMITTED BY
 APPLICABLE LAW. EXCEPT WHEN OTHERWISE STATED IN WRITING THE COPYRIGHT
 HOLDERS AND/OR OTHER PARTIES PROVIDE THE PROGRAM "AS IS" WITHOUT
 WARRANTY OF ANY KIND, EITHER EXPRESSED OR IMPLIED, INCLUDING, BUT NOT
 LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 A PARTICULAR PURPOSE. THE ENTIRE RISK AS TO THE QUALITY AND
 PERFORMANCE OF THE PROGRAM IS WITH YOU. SHOULD THE PROGRAM PROVE
 DEFECTIVE, YOU ASSUME THE COST OF ALL NECESSARY SERVICING, REPAIR OR
 CORRECTION.
 ### 16. Limitation of Liability.
 IN NO EVENT UNLESS REQUIRED BY APPLICABLE LAW OR AGREED TO IN WRITING
 WILL ANY COPYRIGHT HOLDER, OR ANY OTHER PARTY WHO MODIFIES AND/OR
 CONVEYS THE PROGRAM AS PERMITTED ABOVE, BE LIABLE TO YOU FOR DAMAGES,
 INCLUDING ANY GENERAL, SPECIAL, INCIDENTAL OR CONSEQUENTIAL DAMAGES
 ARISING OUT OF THE USE OR INABILITY TO USE THE PROGRAM (INCLUDING BUT
 NOT LIMITED TO LOSS OF DATA OR DATA BEING RENDERED INACCURATE OR
 LOSSES SUSTAINED BY YOU OR THIRD PARTIES OR A FAILURE OF THE PROGRAM
 TO OPERATE WITH ANY OTHER PROGRAMS), EVEN IF SUCH HOLDER OR OTHER
 PARTY HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES.
 ### 17. Interpretation of Sections 15 and 16.
 If the disclaimer of warranty and limitation of liability provided
 above cannot be given local legal effect according to their terms,
 reviewing courts shall apply local law that most closely approximates
 an absolute waiver of all civil liability in connection with the
 Program, unless a warranty or assumption of liability accompanies a
 copy of the Program in return for a fee.
 END OF TERMS AND CONDITIONS
 ## How to Apply These Terms to Your New Programs
 If you develop a new program, and you want it to be of the greatest
 possible use to the public, the best way to achieve this is to make it
 free software which everyone can redistribute and change under these
 terms.
 To do so, attach the following notices to the program. It is safest to
 attach them to the start of each source file to most effectively state
 the exclusion of warranty; and each file should have at least the
 "copyright" line and a pointer to where the full notice is found.
        <one line to give the program's name and a brief idea of what it does.>
        Copyright (C) <year>  <name of author>
        This program is free software: you can redistribute it and/or modify
        it under the terms of the GNU General Public License as published by
        the Free Software Foundation, either version 3 of the License, or
        (at your option) any later version.
        This program is distributed in the hope that it will be useful,
        but WITHOUT ANY WARRANTY; without even the implied warranty of
        MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
        GNU General Public License for more details.
        You should have received a copy of the GNU General Public License
        along with this program.  If not, see <https://www.gnu.org/licenses/>.
 Also add information on how to contact you by electronic and paper
 mail.
 If the program does terminal interaction, make it output a short
 notice like this when it starts in an interactive mode:
        <program>  Copyright (C) <year>  <name of author>
        This program comes with ABSOLUTELY NO WARRANTY; for details type `show w'.
        This is free software, and you are welcome to redistribute it
        under certain conditions; type `show c' for details.
 The hypothetical commands \`show w' and \`show c' should show the
 appropriate parts of the General Public License. Of course, your
 program's commands might be different; for a GUI interface, you would
 use an "about box".
 You should also get your employer (if you work as a programmer) or
 school, if any, to sign a "copyright disclaimer" for the program, if
 necessary. For more information on this, and how to apply and follow
 the GNU GPL, see <https://www.gnu.org/licenses/>.
 The GNU General Public License does not permit incorporating your
 program into proprietary programs. If your program is a subroutine
 library, you may consider it more useful to permit linking proprietary
 applications with the library. If this is what you want to do, use the
 GNU Lesser General Public License instead of this License. But first,
 please read <https://www.gnu.org/licenses/why-not-lgpl.html>.
--- a/README.md
+++ b/README.md
@ -1,28 +1,171 @@
 # Arcaea Offline OCR
 [![Ruff](https://img.shields.io/endpoint?url=https://raw.githubusercontent.com/astral-sh/ruff/main/assets/badge/v2.json)](https://github.com/astral-sh/ruff)
 ## Example
 > Results from `arcaea_offline_ocr 0.1.0a2`
 ### Build an image hash database (ihdb)
 ```py
-from arcaea_offline_ocr.device.v2.rois import DeviceV2AutoRois
+import sqlite3
-from arcaea_offline_ocr.device.v2.ocr import DeviceV2Ocr
+from pathlib import Path
-from arcaea_offline_ocr.sift_db import SIFTDatabase
+
 from arcaea_offline_ocr.utils import imread_unicode
 import cv2
-knn_model = cv2.ml.KNearest_load(r'/path/to/knn/model')
+from arcaea_offline_ocr.builders.ihdb import (
-sift_db = SIFTDatabase(r'/path/to/sift/database.db')
+    ImageHashDatabaseBuildTask,
    ImageHashesDatabaseBuilder,
 )
 from arcaea_offline_ocr.providers import ImageCategory, ImageHashDatabaseIdProvider
 from arcaea_offline_ocr.scenarios.device import DeviceScenario
-rois = DeviceV2AutoRois(imread_unicode(r'/path/to/your/screenshot.jpg'))  # any format that opencv-python supports
+def build():
-ocr = DeviceV2Ocr(knn_model, sift_db)
+    def _read_partner_icon(image_path: str):
-result = ocr.ocr(rois)
+        return DeviceScenario.preprocess_char_icon(
-print(result)
+            cv2.cvtColor(cv2.imread(image_path, cv2.IMREAD_COLOR), cv2.COLOR_BGR2GRAY),
        )
    builder = ImageHashesDatabaseBuilder()
    tasks = [
        ImageHashDatabaseBuildTask(
            image_path=str(file),
            image_id=file.stem,
            category=ImageCategory.JACKET,
        )
        for file in Path("/path/to/some/jackets").glob("*.jpg")
    ]
    tasks.extend(
        [
            ImageHashDatabaseBuildTask(
                image_path=str(file),
                image_id=file.stem,
                category=ImageCategory.PARTNER_ICON,
                imread_function=_read_partner_icon,
            )
            for file in Path("/path/to/some/partner_icons").glob("*.png")
        ],
    )
    with sqlite3.connect("/path/to/ihdb-X.Y.Z.db") as conn:
        builder.build(conn, tasks)
 ```
-```sh
+### Device OCR
-$ python example.py
+
-DeviceOcrResult(rating_class=2, pure=1371, far=62, lost=34, score=9558078, max_recall=330, song_id='abstrusedilemma', title=None, clear_type=None)
+```py
 import json
 import sqlite3
 from dataclasses import asdict
 import cv2
 from arcaea_offline_ocr.providers import (
    ImageHashDatabaseIdProvider,
    OcrKNearestTextProvider,
 )
 from arcaea_offline_ocr.scenarios.device import (
    DeviceRoisAutoT2,
    DeviceRoisExtractor,
    DeviceRoisMaskerAutoT2,
    DeviceScenario,
 )
 with sqlite3.connect("/path/to/ihdb-X.Y.Z.db") as conn:
    img = cv2.imread("/path/to/your/screenshot.jpg")
    h, w = img.shape[:2]
    r = DeviceRoisAutoT2(w, h)
    m = DeviceRoisMaskerAutoT2()
    e = DeviceRoisExtractor(img, r)
    scenario = DeviceScenario(
        extractor=e,
        masker=m,
        knn_provider=OcrKNearestTextProvider(
            cv2.ml.KNearest.load("/path/to/knn_model.dat"),
        ),
        image_id_provider=ImageHashDatabaseIdProvider(conn),
    )
    result = scenario.result()
    with open("result.jsonc", "w", encoding="utf-8") as jf:
        json.dump(asdict(result), jf, indent=2, ensure_ascii=False)
 ```
 ```jsonc
 // result.json
 {
  "song_id": "vector",
  "rating_class": 1,
  "score": 9990996,
  "song_id_results": [
    {
      "image_id": "vector",
      "category": 0,
      "confidence": 1.0,
      "image_hash_type": 0
    },
    {
      "image_id": "clotho",
      "category": 0,
      "confidence": 0.71875,
      "image_hash_type": 0
    }
    // 28 more results omitted…
  ],
  "partner_id_results": [
    {
      "image_id": "23",
      "category": 1,
      "confidence": 0.90625,
      "image_hash_type": 0
    },
    {
      "image_id": "45",
      "category": 1,
      "confidence": 0.8828125,
      "image_hash_type": 0
    }
    // 28 more results omitted…
  ],
  "pure": 1000,
  "pure_inaccurate": null,
  "pure_early": null,
  "pure_late": null,
  "far": 2,
  "far_inaccurate": null,
  "far_early": null,
  "far_late": null,
  "lost": 0,
  "played_at": null,
  "max_recall": 1002,
  "clear_status": 2,
  "clear_type": null,
  "modifier": null
 }
 ```
 ## License
 This file is part of arcaea-offline-ocr, as called "This program" below.
 This program is free software: you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation, either version 3 of the License, or
 (at your option) any later version.
 This program is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 You should have received a copy of the GNU General Public License
 along with this program.  If not, see <https://www.gnu.org/licenses/>.
 ## Credits
-[283375/image-sift-database](https://github.com/283375/image-sift-database)
+- [JohannesBuchner/imagehash](https://github.com/JohannesBuchner/imagehash): `arcaea_offline_ocr.core.hashers` implementations reference
--- a/pyproject.toml
+++ b/pyproject.toml
@ -1,27 +1,33 @@
 [build-system]
-requires = ["setuptools>=61.0"]
+requires = ["setuptools>=64", "setuptools-scm>=8"]
 build-backend = "setuptools.build_meta"
 [project]
 dynamic = ["version"]
 name = "arcaea-offline-ocr"
 version = "0.0.95"
 authors = [{ name = "283375", email = "log_283375@163.com" }]
 description = "Extract your Arcaea play result from screenshot."
 readme = "README.md"
 requires-python = ">=3.8"
-dependencies = ["attrs==23.1.0", "numpy==1.26.1", "opencv-python==4.8.1.78"]
+dependencies = ["numpy~=2.3", "opencv-python~=4.11"]
 classifiers = [
  "Development Status :: 3 - Alpha",
  "Programming Language :: Python :: 3",
 ]
-[project.urls]
+[project.optional-dependencies]
-"Homepage" = "https://github.com/283375/arcaea-offline-ocr"
+dev = ["ruff", "pre-commit"]
 "Bug Tracker" = "https://github.com/283375/arcaea-offline-ocr/issues"
-[tool.isort]
+[project.urls]
-profile = "black"
+"Homepage" = "https://github.com/ArcaeaOffline/core-ocr"
-src_paths = ["src/arcaea_offline_ocr"]
+"Bug Tracker" = "https://github.com/ArcaeaOffline/core-ocr/issues"
 [tool.setuptools_scm]
 [tool.pyright]
 ignore = ["**/__debug*.*"]
 [tool.ruff.lint]
 select = ["ALL"]
 ignore = ["ANN", "D", "ERA", "PLR"]
--- a/requirements.dev.txt
+++ b/requirements.dev.txt
@ -1,3 +1,2 @@
-black==23.7.0
+ruff
-isort==5.12.0
+pre-commit
 pre-commit==3.3.3
--- a/requirements.txt
+++ b/requirements.txt
@ -1,3 +1,2 @@
-attrs==23.1.0
+numpy~=2.3
-numpy==1.26.1
+opencv-python~=4.11
 opencv-python==4.8.1.78
--- a/src/arcaea_offline_ocr/init.py
+++ b/src/arcaea_offline_ocr/init.py
@ -1,4 +0,0 @@
 from .crop import *
 from .device import *
 from .ocr import *
 from .utils import *
--- a/src/arcaea_offline_ocr/b30/chieri/v4/init.py
+++ b/src/arcaea_offline_ocr/b30/chieri/v4/init.py
--- a/src/arcaea_offline_ocr/b30/shared.py
+++ b/src/arcaea_offline_ocr/b30/shared.py
@ -1,16 +0,0 @@
 from datetime import datetime
 from typing import Optional, Union
 import attrs
@attrs.define
 class B30OcrResultItem:
    rating_class: int
    score: int
    pure: Optional[int] = None
    far: Optional[int] = None
    lost: Optional[int] = None
    date: Optional[datetime] = None
    title: Optional[str] = None
    song_id: Optional[str] = None
--- a/src/arcaea_offline_ocr/builders/init.py
+++ b/src/arcaea_offline_ocr/builders/init.py
@ -0,0 +1,6 @@
 from .ihdb import ImageHashDatabaseBuildTask, ImageHashesDatabaseBuilder
 __all__ = [
    "ImageHashDatabaseBuildTask",
    "ImageHashesDatabaseBuilder",
 ]
--- a/src/arcaea_offline_ocr/builders/ihdb.py
+++ b/src/arcaea_offline_ocr/builders/ihdb.py
@ -0,0 +1,115 @@
 from __future__ import annotations
 from dataclasses import dataclass
 from datetime import datetime, timezone
 from typing import TYPE_CHECKING, Callable
 import cv2
 from arcaea_offline_ocr.core import hashers
 from arcaea_offline_ocr.providers.ihdb import (
    PROP_KEY_BUILT_AT,
    PROP_KEY_HASH_SIZE,
    PROP_KEY_HIGH_FREQ_FACTOR,
    ImageHashDatabaseIdProvider,
    ImageHashType,
 )
 if TYPE_CHECKING:
    from sqlite3 import Connection
    from arcaea_offline_ocr.providers import ImageCategory
    from arcaea_offline_ocr.types import Mat
 def _default_imread_gray(image_path: str):
    return cv2.cvtColor(cv2.imread(image_path, cv2.IMREAD_COLOR), cv2.COLOR_BGR2GRAY)
@dataclass
 class ImageHashDatabaseBuildTask:
    image_path: str
    image_id: str
    category: ImageCategory
    imread_function: Callable[[str], Mat] = _default_imread_gray
@dataclass
 class _ImageHash:
    image_id: str
    category: ImageCategory
    image_hash_type: ImageHashType
    hash: bytes
 class ImageHashesDatabaseBuilder:
    @staticmethod
    def __insert_property(conn: Connection, key: str, value: str):
        return conn.execute(
            "INSERT INTO properties (key, value) VALUES (?, ?)",
            (key, value),
        )
    @classmethod
    def build(
        cls,
        conn: Connection,
        tasks: list[ImageHashDatabaseBuildTask],
        *,
        hash_size: int = 16,
        high_freq_factor: int = 4,
    ):
        hashes: list[_ImageHash] = []
        for task in tasks:
            img_gray = task.imread_function(task.image_path)
            for hash_type, hash_mat in [
                (
                    ImageHashType.AVERAGE,
                    hashers.average(img_gray, hash_size),
                ),
                (
                    ImageHashType.DCT,
                    hashers.dct(img_gray, hash_size, high_freq_factor),
                ),
                (
                    ImageHashType.DIFFERENCE,
                    hashers.difference(img_gray, hash_size),
                ),
            ]:
                hashes.append(
                    _ImageHash(
                        image_id=task.image_id,
                        image_hash_type=hash_type,
                        category=task.category,
                        hash=ImageHashDatabaseIdProvider.hash_mat_to_bytes(hash_mat),
                    ),
                )
        conn.execute("CREATE TABLE properties (`key` VARCHAR, `value` VARCHAR)")
        conn.execute(
            """CREATE TABLE hashes (
 `id` VARCHAR,
 `category` INTEGER,
 `hash_type` INTEGER,
 `hash` BLOB
 )""",
        )
        now = datetime.now(tz=timezone.utc)
        timestamp = int(now.timestamp() * 1000)
        cls.__insert_property(conn, PROP_KEY_HASH_SIZE, str(hash_size))
        cls.__insert_property(conn, PROP_KEY_HIGH_FREQ_FACTOR, str(high_freq_factor))
        cls.__insert_property(conn, PROP_KEY_BUILT_AT, str(timestamp))
        conn.executemany(
            """INSERT INTO hashes (`id`, `category`, `hash_type`, `hash`)
                            VALUES (?, ?, ?, ?)""",
            [
                (it.image_id, it.category.value, it.image_hash_type.value, it.hash)
                for it in hashes
            ],
        )
        conn.commit()
--- a/src/arcaea_offline_ocr/core/init.py
+++ b/src/arcaea_offline_ocr/core/init.py
--- a/src/arcaea_offline_ocr/core/hashers/init.py
+++ b/src/arcaea_offline_ocr/core/hashers/init.py
@ -0,0 +1,3 @@
 from .index import average, dct, difference
 __all__ = ["average", "dct", "difference"]
--- a/src/arcaea_offline_ocr/core/hashers/_common.py
+++ b/src/arcaea_offline_ocr/core/hashers/_common.py
@ -0,0 +1,7 @@
 import cv2
 from arcaea_offline_ocr.types import Mat
 def _resize_image(src: Mat, dsize: ...) -> Mat:
    return cv2.resize(src, dsize, fx=0, fy=0, interpolation=cv2.INTER_AREA)
--- a/src/arcaea_offline_ocr/core/hashers/index.py
+++ b/src/arcaea_offline_ocr/core/hashers/index.py
@ -0,0 +1,35 @@
 import cv2
 import numpy as np
 from arcaea_offline_ocr.types import Mat
 from ._common import _resize_image
 def average(img_gray: Mat, hash_size: int) -> Mat:
    img_resized = _resize_image(img_gray, (hash_size, hash_size))
    diff = img_resized > img_resized.mean()
    return diff.flatten()
 def difference(img_gray: Mat, hash_size: int) -> Mat:
    img_size = (hash_size + 1, hash_size)
    img_resized = _resize_image(img_gray, img_size)
    previous = img_resized[:, :-1]
    current = img_resized[:, 1:]
    diff = previous > current
    return diff.flatten()
 def dct(img_gray: Mat, hash_size: int = 16, high_freq_factor: int = 4) -> Mat:
    # TODO: consistency?  # noqa: FIX002, TD002, TD003
    img_size_base = hash_size * high_freq_factor
    img_size = (img_size_base, img_size_base)
    img_resized = _resize_image(img_gray, img_size)
    img_resized = img_resized.astype(np.float32)
    dct_mat = cv2.dct(img_resized)
    hash_mat = dct_mat[:hash_size, :hash_size]
    return hash_mat > hash_mat.mean()
--- a/src/arcaea_offline_ocr/crop.py
+++ b/src/arcaea_offline_ocr/crop.py
@ -1,29 +1,32 @@
 from __future__ import annotations
 import math
-from typing import Tuple
+from typing import TYPE_CHECKING
 import cv2
 import numpy as np
 if TYPE_CHECKING:
    from .types import Mat
-__all__ = ["crop_xywh", "CropBlackEdges"]
+__all__ = ["CropBlackEdges", "crop_xywh"]
-def crop_xywh(mat: Mat, rect: Tuple[int, int, int, int]):
+def crop_xywh(mat: Mat, rect: tuple[int, int, int, int]):
    x, y, w, h = rect
    return mat[y : y + h, x : x + w]
 class CropBlackEdges:
    @staticmethod
-    def is_black_edge(__img_gray_slice: Mat, black_pixel: int, ratio: float = 0.6):
+    def is_black_edge(img_gray_slice: Mat, black_pixel: int, ratio: float = 0.6):
-        pixels_compared = __img_gray_slice < black_pixel
+        pixels_compared = img_gray_slice < black_pixel
        return np.count_nonzero(pixels_compared) > math.floor(
-            __img_gray_slice.size * ratio
+            img_gray_slice.size * ratio,
        )
    @classmethod
-    def get_crop_rect(cls, img_gray: Mat, black_threshold: int = 25):
+    def get_crop_rect(cls, img_gray: Mat, black_threshold: int = 25):  # noqa: C901
        height, width = img_gray.shape[:2]
        left = 0
        right = width
@ -54,13 +57,22 @@ class CropBlackEdges:
                break
            bottom -= 1
-        assert right > left, "cropped width < 0"
+        if right <= left:
-        assert bottom > top, "cropped height < 0"
+            msg = "cropped width < 0"
            raise ValueError(msg)
        if bottom <= top:
            msg = "cropped height < 0"
            raise ValueError(msg)
        return (left, top, right - left, bottom - top)
    @classmethod
    def crop(
-        cls, img: Mat, convert_flag: cv2.COLOR_BGR2GRAY, black_threshold: int = 25
+        cls,
        img: Mat,
        convert_flag: cv2.COLOR_BGR2GRAY,
        black_threshold: int = 25,
    ) -> Mat:
        rect = cls.get_crop_rect(cv2.cvtColor(img, convert_flag), black_threshold)
        return crop_xywh(img, rect)
--- a/src/arcaea_offline_ocr/device/init.py
+++ b/src/arcaea_offline_ocr/device/init.py
@ -1,2 +0,0 @@
 from .common import DeviceOcrResult
 from .ocr import DeviceOcr
--- a/src/arcaea_offline_ocr/device/common.py
+++ b/src/arcaea_offline_ocr/device/common.py
@ -1,18 +0,0 @@
 from typing import Optional
 import attrs
@attrs.define
 class DeviceOcrResult:
    rating_class: int
    pure: int
    far: int
    lost: int
    score: int
    max_recall: Optional[int] = None
    song_id: Optional[str] = None
    song_id_possibility: Optional[float] = None
    clear_status: Optional[int] = None
    partner_id: Optional[str] = None
    partner_id_possibility: Optional[float] = None
--- a/src/arcaea_offline_ocr/device/rois/init.py
+++ b/src/arcaea_offline_ocr/device/rois/init.py
@ -1,3 +0,0 @@
 from .definition import *
 from .extractor import *
 from .masker import *
--- a/src/arcaea_offline_ocr/device/rois/definition/init.py
+++ b/src/arcaea_offline_ocr/device/rois/definition/init.py
@ -1,2 +0,0 @@
 from .auto import *
 from .common import DeviceRois
--- a/src/arcaea_offline_ocr/device/rois/definition/common.py
+++ b/src/arcaea_offline_ocr/device/rois/definition/common.py
@ -1,15 +0,0 @@
 from typing import Tuple
 Rect = Tuple[int, int, int, int]
 class DeviceRois:
    pure: Rect
    far: Rect
    lost: Rect
    score: Rect
    rating_class: Rect
    max_recall: Rect
    jacket: Rect
    clear_status: Rect
    partner_icon: Rect
--- a/src/arcaea_offline_ocr/device/rois/definition/custom.py
+++ b/src/arcaea_offline_ocr/device/rois/definition/custom.py
--- a/src/arcaea_offline_ocr/device/rois/extractor/init.py
+++ b/src/arcaea_offline_ocr/device/rois/extractor/init.py
@ -1 +0,0 @@
 from .common import DeviceRoisExtractor
--- a/src/arcaea_offline_ocr/device/rois/extractor/common.py
+++ b/src/arcaea_offline_ocr/device/rois/extractor/common.py
@ -1,48 +0,0 @@
 from ....crop import crop_xywh
 from ....types import Mat
 from ..definition.common import DeviceRois
 class DeviceRoisExtractor:
    def __init__(self, img: Mat, rois: DeviceRois):
        self.img = img
        self.sizes = rois
    def __construct_int_rect(self, rect):
        return tuple(round(r) for r in rect)
    @property
    def pure(self):
        return crop_xywh(self.img, self.__construct_int_rect(self.sizes.pure))
    @property
    def far(self):
        return crop_xywh(self.img, self.__construct_int_rect(self.sizes.far))
    @property
    def lost(self):
        return crop_xywh(self.img, self.__construct_int_rect(self.sizes.lost))
    @property
    def score(self):
        return crop_xywh(self.img, self.__construct_int_rect(self.sizes.score))
    @property
    def jacket(self):
        return crop_xywh(self.img, self.__construct_int_rect(self.sizes.jacket))
    @property
    def rating_class(self):
        return crop_xywh(self.img, self.__construct_int_rect(self.sizes.rating_class))
    @property
    def max_recall(self):
        return crop_xywh(self.img, self.__construct_int_rect(self.sizes.max_recall))
    @property
    def clear_status(self):
        return crop_xywh(self.img, self.__construct_int_rect(self.sizes.clear_status))
    @property
    def partner_icon(self):
        return crop_xywh(self.img, self.__construct_int_rect(self.sizes.partner_icon))
--- a/src/arcaea_offline_ocr/device/rois/masker/init.py
+++ b/src/arcaea_offline_ocr/device/rois/masker/init.py
@ -1,2 +0,0 @@
 from .auto import *
 from .common import DeviceRoisMasker
--- a/src/arcaea_offline_ocr/device/rois/masker/common.py
+++ b/src/arcaea_offline_ocr/device/rois/masker/common.py
@ -1,55 +0,0 @@
 from ....types import Mat
 class DeviceRoisMasker:
    @classmethod
    def pure(cls, roi_bgr: Mat) -> Mat:
        raise NotImplementedError()
    @classmethod
    def far(cls, roi_bgr: Mat) -> Mat:
        raise NotImplementedError()
    @classmethod
    def lost(cls, roi_bgr: Mat) -> Mat:
        raise NotImplementedError()
    @classmethod
    def score(cls, roi_bgr: Mat) -> Mat:
        raise NotImplementedError()
    @classmethod
    def rating_class_pst(cls, roi_bgr: Mat) -> Mat:
        raise NotImplementedError()
    @classmethod
    def rating_class_prs(cls, roi_bgr: Mat) -> Mat:
        raise NotImplementedError()
    @classmethod
    def rating_class_ftr(cls, roi_bgr: Mat) -> Mat:
        raise NotImplementedError()
    @classmethod
    def rating_class_byd(cls, roi_bgr: Mat) -> Mat:
        raise NotImplementedError()
    @classmethod
    def max_recall(cls, roi_bgr: Mat) -> Mat:
        raise NotImplementedError()
    @classmethod
    def clear_status_track_lost(cls, roi_bgr: Mat) -> Mat:
        raise NotImplementedError()
    @classmethod
    def clear_status_track_complete(cls, roi_bgr: Mat) -> Mat:
        raise NotImplementedError()
    @classmethod
    def clear_status_full_recall(cls, roi_bgr: Mat) -> Mat:
        raise NotImplementedError()
    @classmethod
    def clear_status_pure_memory(cls, roi_bgr: Mat) -> Mat:
        raise NotImplementedError()
--- a/src/arcaea_offline_ocr/phash_db.py
+++ b/src/arcaea_offline_ocr/phash_db.py
@ -1,118 +0,0 @@
 import sqlite3
 from typing import List, Union
 import cv2
 import numpy as np
 from .types import Mat
 def phash_opencv(img_gray, hash_size=8, highfreq_factor=4):
    # type: (Union[Mat, np.ndarray], int, int) -> np.ndarray
    """
    Perceptual Hash computation.
    Implementation follows http://www.hackerfactor.com/blog/index.php?/archives/432-Looks-Like-It.html
    Adapted from `imagehash.phash`, pure opencv implementation
    The result is slightly different from `imagehash.phash`.
    """
    if hash_size < 2:
        raise ValueError("Hash size must be greater than or equal to 2")
    img_size = hash_size * highfreq_factor
    image = cv2.resize(img_gray, (img_size, img_size), interpolation=cv2.INTER_LANCZOS4)
    image = np.float32(image)
    dct = cv2.dct(image)
    dctlowfreq = dct[:hash_size, :hash_size]
    med = np.median(dctlowfreq)
    diff = dctlowfreq > med
    return diff
 def hamming_distance_sql_function(user_input, db_entry) -> int:
    return np.count_nonzero(
        np.frombuffer(user_input, bool) ^ np.frombuffer(db_entry, bool)
    )
 class ImagePhashDatabase:
    def __init__(self, db_path: str):
        with sqlite3.connect(db_path) as conn:
            self.hash_size = int(
                conn.execute(
                    "SELECT value FROM properties WHERE key = 'hash_size'"
                ).fetchone()[0]
            )
            self.highfreq_factor = int(
                conn.execute(
                    "SELECT value FROM properties WHERE key = 'highfreq_factor'"
                ).fetchone()[0]
            )
            self.built_timestamp = int(
                conn.execute(
                    "SELECT value FROM properties WHERE key = 'built_timestamp'"
                ).fetchone()[0]
            )
            self.ids: List[str] = [
                i[0] for i in conn.execute("SELECT id FROM hashes").fetchall()
            ]
            self.hashes_byte = [
                i[0] for i in conn.execute("SELECT hash FROM hashes").fetchall()
            ]
            self.hashes = [np.frombuffer(hb, bool) for hb in self.hashes_byte]
            self.jacket_ids: List[str] = []
            self.jacket_hashes = []
            self.partner_icon_ids: List[str] = []
            self.partner_icon_hashes = []
            for id, hash in zip(self.ids, self.hashes):
                id_splitted = id.split("||")
                if len(id_splitted) > 1 and id_splitted[0] == "partner_icon":
                    self.partner_icon_ids.append(id_splitted[1])
                    self.partner_icon_hashes.append(hash)
                else:
                    self.jacket_ids.append(id)
                    self.jacket_hashes.append(hash)
    def calculate_phash(self, img_gray: Mat):
        return phash_opencv(
            img_gray, hash_size=self.hash_size, highfreq_factor=self.highfreq_factor
        )
    def lookup_hash(self, image_hash: np.ndarray, *, limit: int = 5):
        image_hash = image_hash.flatten()
        xor_results = [
            (id, np.count_nonzero(image_hash ^ h))
            for id, h in zip(self.ids, self.hashes)
        ]
        return sorted(xor_results, key=lambda r: r[1])[:limit]
    def lookup_image(self, img_gray: Mat):
        image_hash = self.calculate_phash(img_gray)
        return self.lookup_hash(image_hash)[0]
    def lookup_jackets(self, img_gray: Mat, *, limit: int = 5):
        image_hash = self.calculate_phash(img_gray).flatten()
        xor_results = [
            (id, np.count_nonzero(image_hash ^ h))
            for id, h in zip(self.jacket_ids, self.jacket_hashes)
        ]
        return sorted(xor_results, key=lambda r: r[1])[:limit]
    def lookup_jacket(self, img_gray: Mat):
        return self.lookup_jackets(img_gray)[0]
    def lookup_partner_icons(self, img_gray: Mat, *, limit: int = 5):
        image_hash = self.calculate_phash(img_gray).flatten()
        xor_results = [
            (id, np.count_nonzero(image_hash ^ h))
            for id, h in zip(self.partner_icon_ids, self.partner_icon_hashes)
        ]
        return sorted(xor_results, key=lambda r: r[1])[:limit]
    def lookup_partner_icon(self, img_gray: Mat):
        return self.lookup_partner_icons(img_gray)[0]
--- a/src/arcaea_offline_ocr/providers/init.py
+++ b/src/arcaea_offline_ocr/providers/init.py
@ -0,0 +1,12 @@
 from .base import ImageCategory, ImageIdProvider, ImageIdProviderResult, OcrTextProvider
 from .ihdb import ImageHashDatabaseIdProvider
 from .knn import OcrKNearestTextProvider
 __all__ = [
    "ImageCategory",
    "ImageHashDatabaseIdProvider",
    "ImageIdProvider",
    "ImageIdProviderResult",
    "OcrKNearestTextProvider",
    "OcrTextProvider",
 ]
--- a/src/arcaea_offline_ocr/providers/base.py
+++ b/src/arcaea_offline_ocr/providers/base.py
@ -0,0 +1,50 @@
 from __future__ import annotations
 from abc import ABC, abstractmethod
 from dataclasses import dataclass
 from enum import IntEnum
 from typing import TYPE_CHECKING, Any, Sequence
 if TYPE_CHECKING:
    from arcaea_offline_ocr.types import Mat
 class OcrTextProvider(ABC):
    @abstractmethod
    def result_raw(self, img: Mat, /, *args, **kwargs) -> Any: ...
    @abstractmethod
    def result(self, img: Mat, /, *args, **kwargs) -> str | None: ...
 class ImageCategory(IntEnum):
    JACKET = 0
    PARTNER_ICON = 1
@dataclass(kw_only=True)
 class ImageIdProviderResult:
    image_id: str
    category: ImageCategory
    confidence: float
 class ImageIdProvider(ABC):
    @abstractmethod
    def result(
        self,
        img: Mat,
        category: ImageCategory,
        /,
        *args,
        **kwargs,
    ) -> ImageIdProviderResult: ...
    @abstractmethod
    def results(
        self,
        img: Mat,
        category: ImageCategory,
        /,
        *args,
        **kwargs,
    ) -> Sequence[ImageIdProviderResult]: ...
--- a/src/arcaea_offline_ocr/providers/ihdb.py
+++ b/src/arcaea_offline_ocr/providers/ihdb.py
@ -0,0 +1,203 @@
 from __future__ import annotations
 from dataclasses import dataclass
 from datetime import datetime, timezone
 from enum import IntEnum
 from typing import TYPE_CHECKING, Any, Callable, TypeVar
 from arcaea_offline_ocr.core import hashers
 from .base import ImageCategory, ImageIdProvider, ImageIdProviderResult
 if TYPE_CHECKING:
    import sqlite3
    from arcaea_offline_ocr.types import Mat
 T = TypeVar("T")
 PROP_KEY_HASH_SIZE = "hash_size"
 PROP_KEY_HIGH_FREQ_FACTOR = "high_freq_factor"
 PROP_KEY_BUILT_AT = "built_at"
 def _sql_hamming_distance(hash1: bytes, hash2: bytes):
    if len(hash1) != len(hash2):
        msg = "hash size does not match!"
        raise ValueError(msg)
    return sum(1 for byte1, byte2 in zip(hash1, hash2) if byte1 != byte2)
 class ImageHashType(IntEnum):
    AVERAGE = 0
    DIFFERENCE = 1
    DCT = 2
@dataclass(kw_only=True)
 class ImageHashDatabaseIdProviderResult(ImageIdProviderResult):
    image_hash_type: ImageHashType
 class MissingPropertiesError(Exception):
    keys: list[str]
    def __init__(self, keys, *args):
        super().__init__(*args)
        self.keys = keys
 class ImageHashDatabaseIdProvider(ImageIdProvider):
    def __init__(self, conn: sqlite3.Connection):
        self.conn = conn
        self.conn.create_function("HAMMING_DISTANCE", 2, _sql_hamming_distance)
        self.properties = {
            PROP_KEY_HASH_SIZE: -1,
            PROP_KEY_HIGH_FREQ_FACTOR: -1,
            PROP_KEY_BUILT_AT: None,
        }
        self._hashes_count = {
            ImageCategory.JACKET: 0,
            ImageCategory.PARTNER_ICON: 0,
        }
        self._hash_length: int = -1
        self._initialize()
    @property
    def hash_size(self) -> int:
        return self.properties[PROP_KEY_HASH_SIZE]
    @property
    def high_freq_factor(self) -> int:
        return self.properties[PROP_KEY_HIGH_FREQ_FACTOR]
    @property
    def built_at(self) -> datetime | None:
        return self.properties.get(PROP_KEY_BUILT_AT)
    @property
    def hash_length(self):
        return self._hash_length
    def _initialize(self):
        def get_property(key, converter: Callable[[Any], T]) -> T | None:
            result = self.conn.execute(
                "SELECT value FROM properties WHERE key = ?",
                (key,),
            ).fetchone()
            return converter(result[0]) if result is not None else None
        def set_hashes_count(category: ImageCategory):
            self._hashes_count[category] = self.conn.execute(
                "SELECT COUNT(DISTINCT `id`) FROM hashes WHERE category = ?",
                (category.value,),
            ).fetchone()[0]
        properties_converter_map = {
            PROP_KEY_HASH_SIZE: lambda x: int(x),
            PROP_KEY_HIGH_FREQ_FACTOR: lambda x: int(x),
            PROP_KEY_BUILT_AT: lambda ts: datetime.fromtimestamp(
                int(ts) / 1000,
                tz=timezone.utc,
            ),
        }
        required_properties = [PROP_KEY_HASH_SIZE, PROP_KEY_HIGH_FREQ_FACTOR]
        missing_properties = []
        for property_key, converter in properties_converter_map.items():
            value = get_property(property_key, converter)
            if value is None:
                if property_key in required_properties:
                    missing_properties.append(property_key)
                continue
            self.properties[property_key] = value
        if missing_properties:
            raise MissingPropertiesError(keys=missing_properties)
        set_hashes_count(ImageCategory.JACKET)
        set_hashes_count(ImageCategory.PARTNER_ICON)
        self._hash_length = self.hash_size**2
    def lookup_hash(
        self,
        category: ImageCategory,
        hash_type: ImageHashType,
        hash_data: bytes,
    ) -> list[ImageHashDatabaseIdProviderResult]:
        cursor = self.conn.execute(
            """
 SELECT
    `id`,
    HAMMING_DISTANCE(hash, ?) AS distance
 FROM hashes
 WHERE category = ? AND hash_type = ?
 ORDER BY distance ASC LIMIT 10""",
            (hash_data, category.value, hash_type.value),
        )
        results = []
        for id_, distance in cursor.fetchall():
            results.append(
                ImageHashDatabaseIdProviderResult(
                    image_id=id_,
                    category=category,
                    confidence=(self.hash_length - distance) / self.hash_length,
                    image_hash_type=hash_type,
                ),
            )
        return results
    @staticmethod
    def hash_mat_to_bytes(hash_mat: Mat) -> bytes:
        return bytes([255 if b else 0 for b in hash_mat.flatten()])
    def results(self, img: Mat, category: ImageCategory, /):
        results: list[ImageHashDatabaseIdProviderResult] = []
        results.extend(
            self.lookup_hash(
                category,
                ImageHashType.AVERAGE,
                self.hash_mat_to_bytes(hashers.average(img, self.hash_size)),
            ),
        )
        results.extend(
            self.lookup_hash(
                category,
                ImageHashType.DIFFERENCE,
                self.hash_mat_to_bytes(hashers.difference(img, self.hash_size)),
            ),
        )
        results.extend(
            self.lookup_hash(
                category,
                ImageHashType.DCT,
                self.hash_mat_to_bytes(
                    hashers.dct(img, self.hash_size, self.high_freq_factor),
                ),
            ),
        )
        return results
    def result(
        self,
        img: Mat,
        category: ImageCategory,
        /,
        *,
        hash_type: ImageHashType = ImageHashType.DCT,
    ):
        return next(
            it for it in self.results(img, category) if it.image_hash_type == hash_type
        )
--- a/src/arcaea_offline_ocr/providers/knn.py
+++ b/src/arcaea_offline_ocr/providers/knn.py
@ -1,27 +1,31 @@
 from __future__ import annotations
 import logging
 import math
-from typing import Optional, Sequence, Tuple
+from typing import TYPE_CHECKING, Callable, Sequence
 import cv2
 import numpy as np
-from .crop import crop_xywh
+from arcaea_offline_ocr.crop import crop_xywh
 from .types import Mat
-__all__ = [
+from .base import OcrTextProvider
-    "FixRects",
+
-    "preprocess_hog",
+if TYPE_CHECKING:
-    "ocr_digits_by_contour_get_samples",
+    from cv2.ml import KNearest
-    "ocr_digits_by_contour_knn",
+
-]
+    from arcaea_offline_ocr.types import Mat
 logger = logging.getLogger(__name__)
 class FixRects:
    @staticmethod
    def connect_broken(
-        rects: Sequence[Tuple[int, int, int, int]],
+        rects: Sequence[tuple[int, int, int, int]],
        img_width: int,
        img_height: int,
-        tolerance: Optional[int] = None,
+        tolerance: int | None = None,
    ):
        # for a "broken" digit, please refer to
        # /assets/fix_rects/broken_masked.jpg
@ -36,7 +40,7 @@ class FixRects:
            if rect in consumed_rects:
                continue
-            x, y, w, h = rect
+            x, _, w, h = rect
            # grab those small rects
            if not img_height * 0.1 <= h <= img_height * 0.6:
                continue
@ -46,7 +50,7 @@ class FixRects:
            for other_rect in rects:
                if rect == other_rect:
                    continue
-                ox, oy, ow, oh = other_rect
+                ox, _, ow, _ = other_rect
                if abs(x - ox) < tolerance and abs((x + w) - (ox + ow)) < tolerance:
                    group.append(other_rect)
@ -69,7 +73,7 @@ class FixRects:
    @staticmethod
    def split_connected(
        img_masked: Mat,
-        rects: Sequence[Tuple[int, int, int, int]],
+        rects: Sequence[tuple[int, int, int, int]],
        rect_wh_ratio: float = 1.05,
        width_range_ratio: float = 0.1,
    ):
@ -110,7 +114,7 @@ class FixRects:
            # split the rect
            new_rects.extend(
-                [(rx, ry, x_mid - rx, rh), (x_mid, ry, rx + rw - x_mid, rh)]
+                [(rx, ry, x_mid - rx, rh), (x_mid, ry, rx + rw - x_mid, rh)],
            )
        return_rects = [r for r in rects if r not in connected_rects]
@ -131,11 +135,21 @@ def resize_fill_square(img: Mat, target: int = 20):
    border_size = math.ceil((max(new_w, new_h) - min(new_w, new_h)) / 2)
    if new_w < new_h:
        resized = cv2.copyMakeBorder(
-            resized, 0, 0, border_size, border_size, cv2.BORDER_CONSTANT
+            resized,
            0,
            0,
            border_size,
            border_size,
            cv2.BORDER_CONSTANT,
        )
    else:
        resized = cv2.copyMakeBorder(
-            resized, border_size, border_size, 0, 0, cv2.BORDER_CONSTANT
+            resized,
            border_size,
            border_size,
            0,
            0,
            cv2.BORDER_CONSTANT,
        )
    return cv2.resize(resized, (target, target))
@ -150,31 +164,94 @@ def preprocess_hog(digit_rois):
    return np.float32(samples)
-def ocr_digit_samples_knn(__samples, knn_model: cv2.ml.KNearest, k: int = 4):
+def ocr_digit_samples_knn(samples, knn_model: cv2.ml.KNearest, k: int = 4):
-    _, results, _, _ = knn_model.findNearest(__samples, k)
+    _, results, _, _ = knn_model.findNearest(samples, k)
-    result_list = [int(r) for r in results.ravel()]
+    return [int(r) for r in results.ravel()]
    result_str = "".join(str(r) for r in result_list if r > -1)
    return int(result_str) if result_str else 0
-def ocr_digits_by_contour_get_samples(__roi_gray: Mat, size: int):
+class OcrKNearestTextProvider(OcrTextProvider):
-    roi = __roi_gray.copy()
+    _ContourFilter = Callable[["Mat"], bool]
-    contours, _ = cv2.findContours(roi, cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_NONE)
+    _RectsFilter = Callable[[Sequence[int]], bool]
    rects = [cv2.boundingRect(c) for c in contours]
    rects = FixRects.connect_broken(rects, roi.shape[1], roi.shape[0])
    rects = FixRects.split_connected(roi, rects)
    rects = sorted(rects, key=lambda r: r[0])
    # digit_rois = [cv2.resize(crop_xywh(roi, rect), size) for rect in rects]
    digit_rois = [resize_fill_square(crop_xywh(roi, rect), size) for rect in rects]
    return preprocess_hog(digit_rois)
    def __init__(self, model: KNearest):
        self.model = model
-def ocr_digits_by_contour_knn(
+    def contours(
-    __roi_gray: Mat,
+        self,
-    knn_model: cv2.ml.KNearest,
+        img: Mat,
        /,
        *,
-    k=4,
+        contours_filter: _ContourFilter | None = None,
-    size: int = 20,
+    ):
-) -> int:
+        cnts, _ = cv2.findContours(img, cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_NONE)
-    samples = ocr_digits_by_contour_get_samples(__roi_gray, size)
+        if contours_filter:
-    return ocr_digit_samples_knn(samples, knn_model, k)
+            cnts = list(filter(contours_filter, cnts))
        return cnts
    def result_raw(
        self,
        img: Mat,
        /,
        *,
        fix_rects: bool = True,
        contours_filter: _ContourFilter | None = None,
        rects_filter: _RectsFilter | None = None,
    ):
        """
        :param img: grayscaled roi
        """
        try:
            cnts, _ = cv2.findContours(img, cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_SIMPLE)
            if contours_filter:
                cnts = list(filter(contours_filter, cnts))
            rects = [cv2.boundingRect(cnt) for cnt in cnts]
            if fix_rects and rects_filter:
                rects = FixRects.connect_broken(rects, img.shape[1], img.shape[0])
                rects = list(filter(rects_filter, rects))
                rects = FixRects.split_connected(img, rects)
            elif fix_rects:
                rects = FixRects.connect_broken(rects, img.shape[1], img.shape[0])
                rects = FixRects.split_connected(img, rects)
            elif rects_filter:
                rects = list(filter(rects_filter, rects))
            rects = sorted(rects, key=lambda r: r[0])
            digits = []
            for rect in rects:
                digit = crop_xywh(img, rect)
                digit = resize_fill_square(digit, 20)
                digits.append(digit)
            samples = preprocess_hog(digits)
            return ocr_digit_samples_knn(samples, self.model)
        except Exception:
            logger.exception("Error occurred during KNearest OCR")
            return None
    def result(
        self,
        img: Mat,
        /,
        *,
        fix_rects: bool = True,
        contours_filter: _ContourFilter | None = None,
        rects_filter: _RectsFilter | None = None,
    ):
        """
        :param img: grayscaled roi
        """
        raw = self.result_raw(
            img,
            fix_rects=fix_rects,
            contours_filter=contours_filter,
            rects_filter=rects_filter,
        )
        return (
            "".join(["".join(str(r) for r in raw if r > -1)])
            if raw is not None
            else None
        )
--- a/src/arcaea_offline_ocr/b30/chieri/init.py
+++ b/src/arcaea_offline_ocr/b30/chieri/init.py
--- a/src/arcaea_offline_ocr/scenarios/b30/init.py
+++ b/src/arcaea_offline_ocr/scenarios/b30/init.py
@ -0,0 +1,3 @@
 from .chieri import ChieriBotV4Best30Scenario
 __all__ = ["ChieriBotV4Best30Scenario"]
--- a/src/arcaea_offline_ocr/scenarios/b30/base.py
+++ b/src/arcaea_offline_ocr/scenarios/b30/base.py
@ -0,0 +1,24 @@
 from __future__ import annotations
 from abc import abstractmethod
 from typing import TYPE_CHECKING
 from arcaea_offline_ocr.scenarios.base import OcrScenario, OcrScenarioResult
 if TYPE_CHECKING:
    from arcaea_offline_ocr.types import Mat
 class Best30Scenario(OcrScenario):
    @abstractmethod
    def components(self, img: Mat, /) -> list[Mat]: ...
    @abstractmethod
    def result(self, component_img: Mat, /, *args, **kwargs) -> OcrScenarioResult: ...
    @abstractmethod
    def results(self, img: Mat, /, *args, **kwargs) -> list[OcrScenarioResult]:
        """
        Commonly a shorthand for `[self.result(comp) for comp in self.components(img)]`
        """
        ...
--- a/src/arcaea_offline_ocr/scenarios/b30/chieri/init.py
+++ b/src/arcaea_offline_ocr/scenarios/b30/chieri/init.py
@ -0,0 +1,3 @@
 from .v4 import ChieriBotV4Best30Scenario
 __all__ = ["ChieriBotV4Best30Scenario"]
--- a/src/arcaea_offline_ocr/scenarios/b30/chieri/v4/init.py
+++ b/src/arcaea_offline_ocr/scenarios/b30/chieri/v4/init.py
@ -0,0 +1,3 @@
 from .impl import ChieriBotV4Best30Scenario
 __all__ = ["ChieriBotV4Best30Scenario"]
--- a/src/arcaea_offline_ocr/scenarios/b30/chieri/v4/colors.py
+++ b/src/arcaea_offline_ocr/scenarios/b30/chieri/v4/colors.py
@ -1,19 +1,19 @@
 import numpy as np
 __all__ = [
    "FONT_THRESHOLD",
    "PURE_BG_MIN_HSV",
    "PURE_BG_MAX_HSV",
    "FAR_BG_MIN_HSV",
    "FAR_BG_MAX_HSV",
    "LOST_BG_MIN_HSV",
    "LOST_BG_MAX_HSV",
    "BYD_MIN_HSV",
    "BYD_MAX_HSV",
-    "FTR_MIN_HSV",
+    "BYD_MIN_HSV",
    "FAR_BG_MAX_HSV",
    "FAR_BG_MIN_HSV",
    "FONT_THRESHOLD",
    "FTR_MAX_HSV",
-    "PRS_MIN_HSV",
+    "FTR_MIN_HSV",
    "LOST_BG_MAX_HSV",
    "LOST_BG_MIN_HSV",
    "PRS_MAX_HSV",
    "PRS_MIN_HSV",
    "PURE_BG_MAX_HSV",
    "PURE_BG_MIN_HSV",
 ]
 FONT_THRESHOLD = 160
@ -27,11 +27,11 @@ FAR_BG_MAX_HSV = np.array([20, 255, 255], np.uint8)
 LOST_BG_MIN_HSV = np.array([115, 60, 150], np.uint8)
 LOST_BG_MAX_HSV = np.array([140, 255, 255], np.uint8)
-BYD_MIN_HSV = (158, 120, 0)
+BYD_MIN_HSV = np.array([158, 120, 0], np.uint8)
-BYD_MAX_HSV = (172, 255, 255)
+BYD_MAX_HSV = np.array([172, 255, 255], np.uint8)
-FTR_MIN_HSV = (145, 70, 0)
+FTR_MIN_HSV = np.array([145, 70, 0], np.uint8)
-FTR_MAX_HSV = (160, 255, 255)
+FTR_MAX_HSV = np.array([160, 255, 255], np.uint8)
-PRS_MIN_HSV = (45, 60, 0)
+PRS_MIN_HSV = np.array([45, 60, 0], np.uint8)
-PRS_MAX_HSV = (70, 255, 255)
+PRS_MAX_HSV = np.array([70, 255, 255], np.uint8)
--- a/src/arcaea_offline_ocr/scenarios/b30/chieri/v4/impl.py
+++ b/src/arcaea_offline_ocr/scenarios/b30/chieri/v4/impl.py
@ -1,60 +1,51 @@
-from math import floor
+from __future__ import annotations
-from typing import List, Optional, Tuple
+
 from typing import TYPE_CHECKING
 import cv2
 import numpy as np
-from ....crop import crop_xywh
+from arcaea_offline_ocr.crop import crop_xywh
-from ....ocr import (
+from arcaea_offline_ocr.providers import (
-    FixRects,
+    ImageCategory,
-    ocr_digits_by_contour_knn,
+    ImageIdProvider,
-    preprocess_hog,
+    OcrKNearestTextProvider,
-    resize_fill_square,
+)
 from arcaea_offline_ocr.scenarios.b30.base import Best30Scenario
 from arcaea_offline_ocr.scenarios.base import OcrScenarioResult
 if TYPE_CHECKING:
    from arcaea_offline_ocr.types import Mat
 from .colors import (
    BYD_MAX_HSV,
    BYD_MIN_HSV,
    FAR_BG_MAX_HSV,
    FAR_BG_MIN_HSV,
    FTR_MAX_HSV,
    FTR_MIN_HSV,
    LOST_BG_MAX_HSV,
    LOST_BG_MIN_HSV,
    PRS_MAX_HSV,
    PRS_MIN_HSV,
    PURE_BG_MAX_HSV,
    PURE_BG_MIN_HSV,
 )
 from ....phash_db import ImagePhashDatabase
 from ....types import Mat
 from ....utils import construct_int_xywh_rect
 from ...shared import B30OcrResultItem
 from .colors import *
 from .rois import ChieriBotV4Rois
-class ChieriBotV4Ocr:
+class ChieriBotV4Best30Scenario(Best30Scenario):
    def __init__(
        self,
-        score_knn: cv2.ml.KNearest,
+        score_knn_provider: OcrKNearestTextProvider,
-        pfl_knn: cv2.ml.KNearest,
+        pfl_knn_provider: OcrKNearestTextProvider,
-        phash_db: ImagePhashDatabase,
+        image_id_provider: ImageIdProvider,
-        factor: Optional[float] = 1.0,
+        factor: float = 1.0,
    ):
        self.__score_knn = score_knn
        self.__pfl_knn = pfl_knn
        self.__phash_db = phash_db
        self.__rois = ChieriBotV4Rois(factor)
-
+        self.pfl_knn_provider = pfl_knn_provider
-    @property
+        self.score_knn_provider = score_knn_provider
-    def score_knn(self):
+        self.image_id_provider = image_id_provider
        return self.__score_knn
    @score_knn.setter
    def score_knn(self, knn_digits_model: cv2.ml.KNearest):
        self.__score_knn = knn_digits_model
    @property
    def pfl_knn(self):
        return self.__pfl_knn
    @pfl_knn.setter
    def pfl_knn(self, knn_digits_model: cv2.ml.KNearest):
        self.__pfl_knn = knn_digits_model
    @property
    def phash_db(self):
        return self.__phash_db
    @phash_db.setter
    def phash_db(self, phash_db: ImagePhashDatabase):
        self.__phash_db = phash_db
    @property
    def rois(self):
@ -72,9 +63,8 @@ class ChieriBotV4Ocr:
        self.factor = img.shape[0] / 4400
    def ocr_component_rating_class(self, component_bgr: Mat) -> int:
-        rating_class_rect = construct_int_xywh_rect(
+        rating_class_rect = self.rois.component_rois.rating_class_rect.rounded()
-            self.rois.component_rois.rating_class_rect
+
        )
        rating_class_roi = crop_xywh(component_bgr, rating_class_rect)
        rating_class_roi = cv2.cvtColor(rating_class_roi, cv2.COLOR_BGR2HSV)
        rating_class_masks = [
@ -85,41 +75,50 @@ class ChieriBotV4Ocr:
        rating_class_results = [np.count_nonzero(m) for m in rating_class_masks]
        if max(rating_class_results) < 70:
            return 0
        else:
        return max(enumerate(rating_class_results), key=lambda i: i[1])[0] + 1
-    def ocr_component_song_id(self, component_bgr: Mat):
+    def ocr_component_song_id_results(self, component_bgr: Mat):
-        jacket_rect = construct_int_xywh_rect(
+        jacket_rect = self.rois.component_rois.jacket_rect.floored()
            self.rois.component_rois.jacket_rect, floor
        )
        jacket_roi = cv2.cvtColor(
-            crop_xywh(component_bgr, jacket_rect), cv2.COLOR_BGR2GRAY
+            crop_xywh(component_bgr, jacket_rect),
            cv2.COLOR_BGR2GRAY,
        )
-        return self.phash_db.lookup_jacket(jacket_roi)[0]
+        return self.image_id_provider.results(jacket_roi, ImageCategory.JACKET)
    def ocr_component_score_knn(self, component_bgr: Mat) -> int:
        # sourcery skip: inline-immediately-returned-variable
-        score_rect = construct_int_xywh_rect(self.rois.component_rois.score_rect)
+        score_rect = self.rois.component_rois.score_rect.rounded()
        score_roi = cv2.cvtColor(
-            crop_xywh(component_bgr, score_rect), cv2.COLOR_BGR2GRAY
+            crop_xywh(component_bgr, score_rect),
            cv2.COLOR_BGR2GRAY,
        )
        _, score_roi = cv2.threshold(
-            score_roi, 0, 255, cv2.THRESH_BINARY + cv2.THRESH_OTSU
+            score_roi,
            0,
            255,
            cv2.THRESH_BINARY + cv2.THRESH_OTSU,
        )
        if score_roi[1][1] == 255:
            score_roi = 255 - score_roi
        contours, _ = cv2.findContours(
-            score_roi, cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_SIMPLE
+            score_roi,
            cv2.RETR_EXTERNAL,
            cv2.CHAIN_APPROX_SIMPLE,
        )
        for contour in contours:
            rect = cv2.boundingRect(contour)
            if rect[3] > score_roi.shape[0] * 0.5:
                continue
            score_roi = cv2.fillPoly(score_roi, [contour], 0)
        return ocr_digits_by_contour_knn(score_roi, self.score_knn)
-    def find_pfl_rects(self, component_pfl_processed: Mat) -> List[List[int]]:
+        ocr_result = self.score_knn_provider.result(score_roi)
        return int(ocr_result) if ocr_result else 0
    def find_pfl_rects(
        self,
        component_pfl_processed: Mat,
    ) -> list[tuple[int, int, int, int]]:
        # sourcery skip: inline-immediately-returned-variable
        pfl_roi_find = cv2.morphologyEx(
            component_pfl_processed,
@ -127,14 +126,16 @@ class ChieriBotV4Ocr:
            cv2.getStructuringElement(cv2.MORPH_RECT, [10, 1]),
        )
        pfl_contours, _ = cv2.findContours(
-            pfl_roi_find, cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_NONE
+            pfl_roi_find,
            cv2.RETR_EXTERNAL,
            cv2.CHAIN_APPROX_NONE,
        )
        pfl_rects = [cv2.boundingRect(c) for c in pfl_contours]
        pfl_rects = [
            r for r in pfl_rects if r[3] > component_pfl_processed.shape[0] * 0.1
        ]
        pfl_rects = sorted(pfl_rects, key=lambda r: r[1])
-        pfl_rects_adjusted = [
+        return [
            (
                max(rect[0] - 2, 0),
                rect[1],
@ -143,10 +144,9 @@ class ChieriBotV4Ocr:
            )
            for rect in pfl_rects
        ]
        return pfl_rects_adjusted
    def preprocess_component_pfl(self, component_bgr: Mat) -> Mat:
-        pfl_rect = construct_int_xywh_rect(self.rois.component_rois.pfl_rect)
+        pfl_rect = self.rois.component_rois.pfl_rect.rounded()
        pfl_roi = crop_xywh(component_bgr, pfl_rect)
        pfl_roi_hsv = cv2.cvtColor(pfl_roi, cv2.COLOR_BGR2HSV)
@ -166,11 +166,17 @@ class ChieriBotV4Ocr:
        pfl_roi_blurred = cv2.GaussianBlur(pfl_roi, (5, 5), 0)
        # pfl_roi_blurred = cv2.medianBlur(pfl_roi, 3)
        _, pfl_roi_blurred_threshold = cv2.threshold(
-            pfl_roi_blurred, 0, 255, cv2.THRESH_BINARY + cv2.THRESH_OTSU
+            pfl_roi_blurred,
            0,
            255,
            cv2.THRESH_BINARY + cv2.THRESH_OTSU,
        )
        # and a threshold of the original roi
        _, pfl_roi_threshold = cv2.threshold(
-            pfl_roi, 0, 255, cv2.THRESH_BINARY + cv2.THRESH_OTSU
+            pfl_roi,
            0,
            255,
            cv2.THRESH_BINARY + cv2.THRESH_OTSU,
        )
        # turn thresholds into black background
        if pfl_roi_blurred_threshold[2][2] == 255:
@ -180,64 +186,58 @@ class ChieriBotV4Ocr:
        # return a bitwise_and result
        result = cv2.bitwise_and(pfl_roi_blurred_threshold, pfl_roi_threshold)
        result_eroded = cv2.erode(
-            result, cv2.getStructuringElement(cv2.MORPH_CROSS, (2, 2))
+            result,
            cv2.getStructuringElement(cv2.MORPH_CROSS, (2, 2)),
        )
        return result_eroded if len(self.find_pfl_rects(result_eroded)) == 3 else result
    def ocr_component_pfl(
-        self, component_bgr: Mat
+        self,
-    ) -> Tuple[Optional[int], Optional[int], Optional[int]]:
+        component_bgr: Mat,
    ) -> tuple[int | None, int | None, int | None]:
        try:
            pfl_roi = self.preprocess_component_pfl(component_bgr)
            pfl_rects = self.find_pfl_rects(pfl_roi)
            pure_far_lost = []
            for pfl_roi_rect in pfl_rects:
                roi = crop_xywh(pfl_roi, pfl_roi_rect)
-                digit_contours, _ = cv2.findContours(
+                result = self.pfl_knn_provider.result(roi)
-                    roi, cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_SIMPLE
+                pure_far_lost.append(int(result) if result else None)
                )
                digit_rects = [cv2.boundingRect(c) for c in digit_contours]
                digit_rects = FixRects.connect_broken(
                    digit_rects, roi.shape[1], roi.shape[0]
                )
                digit_rects = FixRects.split_connected(roi, digit_rects)
                digit_rects = sorted(digit_rects, key=lambda r: r[0])
                digits = []
                for digit_rect in digit_rects:
                    digit = crop_xywh(roi, digit_rect)
                    digit = resize_fill_square(digit, 20)
                    digits.append(digit)
                samples = preprocess_hog(digits)
                _, results, _, _ = self.pfl_knn.findNearest(samples, 4)
                results = [str(int(i)) for i in results.ravel()]
                pure_far_lost.append(int("".join(results)))
            return tuple(pure_far_lost)
-        except Exception:
+        except Exception:  # noqa: BLE001
            return (None, None, None)
-    def ocr_component(self, component_bgr: Mat) -> B30OcrResultItem:
+    def ocr_component(self, component_bgr: Mat) -> OcrScenarioResult:
        component_blur = cv2.GaussianBlur(component_bgr, (5, 5), 0)
        rating_class = self.ocr_component_rating_class(component_blur)
-        song_id = self.ocr_component_song_id(component_bgr)
+        song_id_results = self.ocr_component_song_id_results(component_bgr)
        # title = self.ocr_component_title(component_blur)
        # score = self.ocr_component_score(component_blur)
        score = self.ocr_component_score_knn(component_bgr)
        pure, far, lost = self.ocr_component_pfl(component_bgr)
-        return B30OcrResultItem(
+        return OcrScenarioResult(
-            song_id=song_id,
+            song_id=song_id_results[0].image_id,
            song_id_results=song_id_results,
            rating_class=rating_class,
            # title=title,
            score=score,
            pure=pure,
            far=far,
            lost=lost,
-            date=None,
+            played_at=None,
        )
-    def ocr(self, img_bgr: Mat) -> List[B30OcrResultItem]:
+    def components(self, img: Mat, /):
-        self.set_factor(img_bgr)
+        """
-        return [
+        :param img: BGR format image
-            self.ocr_component(component_bgr)
+        """
-            for component_bgr in self.rois.components(img_bgr)
+        self.set_factor(img)
-        ]
+        return self.rois.components(img)
    def result(self, component_img: Mat, /):
        return self.ocr_component(component_img)
    def results(self, img: Mat, /) -> list[OcrScenarioResult]:
        """
        :param img: BGR format image
        """
        return [self.ocr_component(component) for component in self.components(img)]
--- a/src/arcaea_offline_ocr/scenarios/b30/chieri/v4/rois.py
+++ b/src/arcaea_offline_ocr/scenarios/b30/chieri/v4/rois.py
@ -1,12 +1,11 @@
-from typing import List, Optional
+from __future__ import annotations
-from ....crop import crop_xywh
+from arcaea_offline_ocr.crop import crop_xywh
-from ....types import Mat, XYWHRect
+from arcaea_offline_ocr.types import Mat, XYWHRect
 from ....utils import apply_factor, construct_int_xywh_rect
 class ChieriBotV4ComponentRois:
-    def __init__(self, factor: Optional[float] = 1.0):
+    def __init__(self, factor: float = 1.0):
        self.__factor = factor
    @property
@ -19,43 +18,43 @@ class ChieriBotV4ComponentRois:
    @property
    def top_font_color_detect(self):
-        return apply_factor((35, 10, 120, 100), self.factor)
+        return XYWHRect(35, 10, 120, 100), self.factor
    @property
    def bottom_font_color_detect(self):
-        return apply_factor((30, 125, 175, 110), self.factor)
+        return XYWHRect(30, 125, 175, 110) * self.factor
    @property
    def bg_point(self):
-        return apply_factor((75, 10), self.factor)
+        return (75 * self.factor, 10 * self.factor)
    @property
    def rating_class_rect(self):
-        return apply_factor((21, 40, 7, 20), self.factor)
+        return XYWHRect(21, 40, 7, 20) * self.factor
    @property
    def title_rect(self):
-        return apply_factor((35, 10, 430, 50), self.factor)
+        return XYWHRect(35, 10, 430, 50) * self.factor
    @property
    def jacket_rect(self):
-        return apply_factor((263, 0, 239, 239), self.factor)
+        return XYWHRect(263, 0, 239, 239) * self.factor
    @property
    def score_rect(self):
-        return apply_factor((30, 60, 270, 55), self.factor)
+        return XYWHRect(30, 60, 270, 55) * self.factor
    @property
    def pfl_rect(self):
-        return apply_factor((50, 125, 80, 100), self.factor)
+        return XYWHRect(50, 125, 80, 100) * self.factor
    @property
    def date_rect(self):
-        return apply_factor((205, 200, 225, 25), self.factor)
+        return XYWHRect(205, 200, 225, 25) * self.factor
 class ChieriBotV4Rois:
-    def __init__(self, factor: Optional[float] = 1.0):
+    def __init__(self, factor: float = 1.0):
        self.__factor = factor
        self.__component_rois = ChieriBotV4ComponentRois(factor)
@ -74,54 +73,53 @@ class ChieriBotV4Rois:
    @property
    def top(self):
-        return apply_factor(823, self.factor)
+        return 823 * self.factor
    @property
    def left(self):
-        return apply_factor(107, self.factor)
+        return 107 * self.factor
    @property
    def width(self):
-        return apply_factor(502, self.factor)
+        return 502 * self.factor
    @property
    def height(self):
-        return apply_factor(240, self.factor)
+        return 240 * self.factor
    @property
    def vertical_gap(self):
-        return apply_factor(74, self.factor)
+        return 74 * self.factor
    @property
    def horizontal_gap(self):
-        return apply_factor(40, self.factor)
+        return 40 * self.factor
    @property
    def horizontal_items(self):
        return 3
-    @property
+    vertical_items = 10
    def vertical_items(self):
        return 10
    @property
    def b33_vertical_gap(self):
-        return apply_factor(121, self.factor)
+        return 121 * self.factor
-    def components(self, img_bgr: Mat) -> List[Mat]:
+    def components(self, img_bgr: Mat) -> list[Mat]:
        first_rect = XYWHRect(x=self.left, y=self.top, w=self.width, h=self.height)
        results = []
        last_rect = first_rect
        for vi in range(self.vertical_items):
            rect = XYWHRect(*first_rect)
            rect += (0, (self.vertical_gap + self.height) * vi, 0, 0)
            for hi in range(self.horizontal_items):
                if hi > 0:
                    rect += ((self.width + self.horizontal_gap), 0, 0, 0)
-                int_rect = construct_int_xywh_rect(rect)
+                results.append(crop_xywh(img_bgr, rect.rounded()))
-                results.append(crop_xywh(img_bgr, int_rect))
+            last_rect = rect
-        rect += (
+        last_rect += (
            -(self.width + self.horizontal_gap) * 2,
            self.height + self.b33_vertical_gap,
            0,
@ -129,8 +127,7 @@ class ChieriBotV4Rois:
        )
        for hi in range(self.horizontal_items):
            if hi > 0:
-                rect += ((self.width + self.horizontal_gap), 0, 0, 0)
+                last_rect += ((self.width + self.horizontal_gap), 0, 0, 0)
-            int_rect = construct_int_xywh_rect(rect)
+            results.append(crop_xywh(img_bgr, last_rect.rounded()))
            results.append(crop_xywh(img_bgr, int_rect))
        return results
--- a/src/arcaea_offline_ocr/scenarios/base.py
+++ b/src/arcaea_offline_ocr/scenarios/base.py
@ -0,0 +1,42 @@
 from __future__ import annotations
 from abc import ABC
 from dataclasses import dataclass, field
 from typing import TYPE_CHECKING, Sequence
 if TYPE_CHECKING:
    from datetime import datetime
    from arcaea_offline_ocr.providers import ImageIdProviderResult
@dataclass(kw_only=True)
 class OcrScenarioResult:
    song_id: str
    rating_class: int
    score: int
    song_id_results: Sequence[ImageIdProviderResult] = field(default_factory=list)
    partner_id_results: Sequence[ImageIdProviderResult] = field(
        default_factory=list,
    )
    pure: int | None = None
    pure_inaccurate: int | None = None
    pure_early: int | None = None
    pure_late: int | None = None
    far: int | None = None
    far_inaccurate: int | None = None
    far_early: int | None = None
    far_late: int | None = None
    lost: int | None = None
    played_at: datetime | None = None
    max_recall: int | None = None
    clear_status: int | None = None
    clear_type: int | None = None
    modifier: int | None = None
 class OcrScenario(ABC):  # noqa: B024
    pass
--- a/src/arcaea_offline_ocr/scenarios/device/init.py
+++ b/src/arcaea_offline_ocr/scenarios/device/init.py
@ -0,0 +1,13 @@
 from .extractor import DeviceRoisExtractor
 from .impl import DeviceScenario
 from .masker import DeviceRoisMaskerAutoT1, DeviceRoisMaskerAutoT2
 from .rois import DeviceRoisAutoT1, DeviceRoisAutoT2
 __all__ = [
    "DeviceRoisAutoT1",
    "DeviceRoisAutoT2",
    "DeviceRoisExtractor",
    "DeviceRoisMaskerAutoT1",
    "DeviceRoisMaskerAutoT2",
    "DeviceScenario",
 ]
--- a/src/arcaea_offline_ocr/scenarios/device/base.py
+++ b/src/arcaea_offline_ocr/scenarios/device/base.py
@ -0,0 +1,8 @@
 from abc import abstractmethod
 from arcaea_offline_ocr.scenarios.base import OcrScenario, OcrScenarioResult
 class DeviceScenarioBase(OcrScenario):
    @abstractmethod
    def result(self) -> OcrScenarioResult: ...
--- a/src/arcaea_offline_ocr/scenarios/device/extractor/init.py
+++ b/src/arcaea_offline_ocr/scenarios/device/extractor/init.py
@ -0,0 +1,3 @@
 from .base import DeviceRoisExtractor
 __all__ = ["DeviceRoisExtractor"]
--- a/src/arcaea_offline_ocr/scenarios/device/extractor/base.py
+++ b/src/arcaea_offline_ocr/scenarios/device/extractor/base.py
@ -0,0 +1,45 @@
 from arcaea_offline_ocr.crop import crop_xywh
 from arcaea_offline_ocr.scenarios.device.rois import DeviceRois
 from arcaea_offline_ocr.types import Mat
 class DeviceRoisExtractor:
    def __init__(self, img: Mat, rois: DeviceRois):
        self.img = img
        self.sizes = rois
    @property
    def pure(self):
        return crop_xywh(self.img, self.sizes.pure.rounded())
    @property
    def far(self):
        return crop_xywh(self.img, self.sizes.far.rounded())
    @property
    def lost(self):
        return crop_xywh(self.img, self.sizes.lost.rounded())
    @property
    def score(self):
        return crop_xywh(self.img, self.sizes.score.rounded())
    @property
    def jacket(self):
        return crop_xywh(self.img, self.sizes.jacket.rounded())
    @property
    def rating_class(self):
        return crop_xywh(self.img, self.sizes.rating_class.rounded())
    @property
    def max_recall(self):
        return crop_xywh(self.img, self.sizes.max_recall.rounded())
    @property
    def clear_status(self):
        return crop_xywh(self.img, self.sizes.clear_status.rounded())
    @property
    def partner_icon(self):
        return crop_xywh(self.img, self.sizes.partner_icon.rounded())
--- a/src/arcaea_offline_ocr/scenarios/device/impl.py
+++ b/src/arcaea_offline_ocr/scenarios/device/impl.py
@ -1,58 +1,56 @@
 import cv2
 import numpy as np
-from ..crop import crop_xywh
+from arcaea_offline_ocr.providers import (
-from ..ocr import (
+    ImageCategory,
-    FixRects,
+    ImageIdProvider,
-    ocr_digit_samples_knn,
+    OcrKNearestTextProvider,
    ocr_digits_by_contour_knn,
    preprocess_hog,
    resize_fill_square,
 )
-from ..phash_db import ImagePhashDatabase
+from arcaea_offline_ocr.scenarios.base import OcrScenarioResult
-from ..types import Mat
+from arcaea_offline_ocr.types import Mat
-from .common import DeviceOcrResult
+
-from .rois.extractor import DeviceRoisExtractor
+from .base import DeviceScenarioBase
-from .rois.masker import DeviceRoisMasker
+from .extractor import DeviceRoisExtractor
 from .masker import DeviceRoisMasker
-class DeviceOcr:
+class DeviceScenario(DeviceScenarioBase):
    def __init__(
        self,
        extractor: DeviceRoisExtractor,
        masker: DeviceRoisMasker,
-        knn_model: cv2.ml.KNearest,
+        knn_provider: OcrKNearestTextProvider,
-        phash_db: ImagePhashDatabase,
+        image_id_provider: ImageIdProvider,
    ):
        self.extractor = extractor
        self.masker = masker
-        self.knn_model = knn_model
+        self.knn_provider = knn_provider
-        self.phash_db = phash_db
+        self.image_id_provider = image_id_provider
    def pfl(self, roi_gray: Mat, factor: float = 1.25):
-        contours, _ = cv2.findContours(
+        def contour_filter(cnt):
-            roi_gray, cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_NONE
+            return cv2.contourArea(cnt) >= 5 * factor
        )
        filtered_contours = [c for c in contours if cv2.contourArea(c) >= 5 * factor]
        rects = [cv2.boundingRect(c) for c in filtered_contours]
        rects = FixRects.connect_broken(rects, roi_gray.shape[1], roi_gray.shape[0])
-        filtered_rects = [r for r in rects if r[2] >= 5 * factor and r[3] >= 6 * factor]
+        contours = self.knn_provider.contours(roi_gray)
-        filtered_rects = FixRects.split_connected(roi_gray, filtered_rects)
+        contours_filtered = self.knn_provider.contours(
-        filtered_rects = sorted(filtered_rects, key=lambda r: r[0])
+            roi_gray,
            contours_filter=contour_filter,
        )
        roi_ocr = roi_gray.copy()
-        filtered_contours_flattened = {tuple(c.flatten()) for c in filtered_contours}
+        contours_filtered_flattened = {tuple(c.flatten()) for c in contours_filtered}
        for contour in contours:
-            if tuple(contour.flatten()) in filtered_contours_flattened:
+            if tuple(contour.flatten()) in contours_filtered_flattened:
                continue
            roi_ocr = cv2.fillPoly(roi_ocr, [contour], [0])
        digit_rois = [
            resize_fill_square(crop_xywh(roi_ocr, r), 20) for r in filtered_rects
        ]
-        samples = preprocess_hog(digit_rois)
+        ocr_result = self.knn_provider.result(
-        return ocr_digit_samples_knn(samples, self.knn_model)
+            roi_ocr,
            contours_filter=lambda cnt: cv2.contourArea(cnt) >= 5 * factor,
            rects_filter=lambda rect: rect[2] >= 5 * factor and rect[3] >= 6 * factor,
        )
        return int(ocr_result) if ocr_result else 0
    def pure(self):
        return self.pfl(self.masker.pure(self.extractor.pure))
@ -65,12 +63,14 @@ class DeviceOcr:
    def score(self):
        roi = self.masker.score(self.extractor.score)
-        contours, _ = cv2.findContours(roi, cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_NONE)
+        contours = self.knn_provider.contours(roi)
        for contour in contours:
-            x, y, w, h = cv2.boundingRect(contour)
+            if (
-            if h < roi.shape[0] * 0.6:
+                cv2.boundingRect(contour)[3] < roi.shape[0] * 0.6
            ):  # h < score_component_h * 0.6
                roi = cv2.fillPoly(roi, [contour], [0])
-        return ocr_digits_by_contour_knn(roi, self.knn_model)
+        ocr_result = self.knn_provider.result(roi)
        return int(ocr_result) if ocr_result else 0
    def rating_class(self):
        roi = self.extractor.rating_class
@ -79,13 +79,15 @@ class DeviceOcr:
            self.masker.rating_class_prs(roi),
            self.masker.rating_class_ftr(roi),
            self.masker.rating_class_byd(roi),
            self.masker.rating_class_etr(roi),
        ]
        return max(enumerate(results), key=lambda i: np.count_nonzero(i[1]))[0]
    def max_recall(self):
-        return ocr_digits_by_contour_knn(
+        ocr_result = self.knn_provider.result(
-            self.masker.max_recall(self.extractor.max_recall), self.knn_model
+            self.masker.max_recall(self.extractor.max_recall),
        )
        return int(ocr_result) if ocr_result else None
    def clear_status(self):
        roi = self.extractor.clear_status
@ -97,20 +99,18 @@ class DeviceOcr:
        ]
        return max(enumerate(results), key=lambda i: np.count_nonzero(i[1]))[0]
-    def lookup_song_id(self):
+    def song_id_results(self):
-        return self.phash_db.lookup_jacket(
+        return self.image_id_provider.results(
-            cv2.cvtColor(self.extractor.jacket, cv2.COLOR_BGR2GRAY)
+            cv2.cvtColor(self.extractor.jacket, cv2.COLOR_BGR2GRAY),
            ImageCategory.JACKET,
        )
    def song_id(self):
        return self.lookup_song_id()[0]
    @staticmethod
    def preprocess_char_icon(img_gray: Mat):
        h, w = img_gray.shape[:2]
-        img = cv2.copyMakeBorder(img_gray, w - h, 0, 0, 0, cv2.BORDER_REPLICATE)
+        img = cv2.copyMakeBorder(img_gray, max(w - h, 0), 0, 0, 0, cv2.BORDER_REPLICATE)
        h, w = img.shape[:2]
-        img = cv2.fillPoly(
+        return cv2.fillPoly(
            img,
            [
                np.array([[0, 0], [round(w / 2), 0], [0, round(h / 2)]], np.int32),
@ -118,21 +118,18 @@ class DeviceOcr:
                np.array([[0, h], [round(w / 2), h], [0, round(h / 2)]], np.int32),
                np.array([[w, h], [round(w / 2), h], [w, round(h / 2)]], np.int32),
            ],
-            (128),
+            (128,),
        )
        return img
-    def lookup_partner_id(self):
+    def partner_id_results(self):
-        return self.phash_db.lookup_partner_icon(
+        return self.image_id_provider.results(
            self.preprocess_char_icon(
-                cv2.cvtColor(self.extractor.partner_icon, cv2.COLOR_BGR2GRAY)
+                cv2.cvtColor(self.extractor.partner_icon, cv2.COLOR_BGR2GRAY),
-            )
+            ),
            ImageCategory.PARTNER_ICON,
        )
-    def partner_id(self):
+    def result(self):
        return self.lookup_partner_id()[0]
    def ocr(self) -> DeviceOcrResult:
        rating_class = self.rating_class()
        pure = self.pure()
        far = self.far()
@ -141,20 +138,18 @@ class DeviceOcr:
        max_recall = self.max_recall()
        clear_status = self.clear_status()
-        hash_len = self.phash_db.hash_size**2
+        song_id_results = self.song_id_results()
-        song_id, song_id_distance = self.lookup_song_id()
+        partner_id_results = self.partner_id_results()
        partner_id, partner_id_distance = self.lookup_partner_id()
-        return DeviceOcrResult(
+        return OcrScenarioResult(
            song_id=song_id_results[0].image_id,
            song_id_results=song_id_results,
            rating_class=rating_class,
            pure=pure,
            far=far,
            lost=lost,
            score=score,
            max_recall=max_recall,
-            song_id=song_id,
+            partner_id_results=partner_id_results,
            song_id_possibility=1 - song_id_distance / hash_len,
            clear_status=clear_status,
            partner_id=partner_id,
            partner_id_possibility=1 - partner_id_distance / hash_len,
        )
--- a/src/arcaea_offline_ocr/scenarios/device/masker/init.py
+++ b/src/arcaea_offline_ocr/scenarios/device/masker/init.py
@ -0,0 +1,9 @@
 from .auto import DeviceRoisMaskerAuto, DeviceRoisMaskerAutoT1, DeviceRoisMaskerAutoT2
 from .base import DeviceRoisMasker
 __all__ = [
    "DeviceRoisMasker",
    "DeviceRoisMaskerAuto",
    "DeviceRoisMaskerAutoT1",
    "DeviceRoisMaskerAutoT2",
 ]
--- a/src/arcaea_offline_ocr/scenarios/device/masker/auto.py
+++ b/src/arcaea_offline_ocr/scenarios/device/masker/auto.py
@ -1,20 +1,27 @@
 import cv2
 import numpy as np
-from ....types import Mat
+from arcaea_offline_ocr.types import Mat
-from .common import DeviceRoisMasker
+
 from .base import DeviceRoisMasker
 class DeviceRoisMaskerAuto(DeviceRoisMasker):
-    ...
+    @staticmethod
    def mask_bgr_in_hsv(roi_bgr: Mat, hsv_lower: Mat, hsv_upper: Mat):
        return cv2.inRange(
            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV),
            hsv_lower,
            hsv_upper,
        )
 class DeviceRoisMaskerAutoT1(DeviceRoisMaskerAuto):
    GRAY_BGR_MIN = np.array([50] * 3, np.uint8)
    GRAY_BGR_MAX = np.array([160] * 3, np.uint8)
-    WHITE_HSV_MIN = np.array([0, 0, 240], np.uint8)
+    SCORE_HSV_MIN = np.array([0, 0, 180], np.uint8)
-    WHITE_HSV_MAX = np.array([179, 10, 255], np.uint8)
+    SCORE_HSV_MAX = np.array([179, 255, 255], np.uint8)
    PST_HSV_MIN = np.array([100, 50, 80], np.uint8)
    PST_HSV_MAX = np.array([100, 255, 255], np.uint8)
@ -28,6 +35,9 @@ class DeviceRoisMaskerAutoT1(DeviceRoisMaskerAuto):
    BYD_HSV_MIN = np.array([170, 50, 50], np.uint8)
    BYD_HSV_MAX = np.array([179, 210, 198], np.uint8)
    ETR_HSV_MIN = np.array([130, 60, 80], np.uint8)
    ETR_HSV_MAX = np.array([140, 145, 180], np.uint8)
    TRACK_LOST_HSV_MIN = np.array([170, 75, 90], np.uint8)
    TRACK_LOST_HSV_MAX = np.array([175, 170, 160], np.uint8)
@ -63,35 +73,27 @@ class DeviceRoisMaskerAutoT1(DeviceRoisMaskerAuto):
    @classmethod
    def score(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(roi_bgr, cls.SCORE_HSV_MIN, cls.SCORE_HSV_MAX)
            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV),
            cls.WHITE_HSV_MIN,
            cls.WHITE_HSV_MAX,
        )
    @classmethod
    def rating_class_pst(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(roi_bgr, cls.PST_HSV_MIN, cls.PST_HSV_MAX)
            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV), cls.PST_HSV_MIN, cls.PST_HSV_MAX
        )
    @classmethod
    def rating_class_prs(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(roi_bgr, cls.PRS_HSV_MIN, cls.PRS_HSV_MAX)
            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV), cls.PRS_HSV_MIN, cls.PRS_HSV_MAX
        )
    @classmethod
    def rating_class_ftr(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(roi_bgr, cls.FTR_HSV_MIN, cls.FTR_HSV_MAX)
            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV), cls.FTR_HSV_MIN, cls.FTR_HSV_MAX
        )
    @classmethod
    def rating_class_byd(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(roi_bgr, cls.BYD_HSV_MIN, cls.BYD_HSV_MAX)
-            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV), cls.BYD_HSV_MIN, cls.BYD_HSV_MAX
+
-        )
+    @classmethod
    def rating_class_etr(cls, roi_bgr: Mat) -> Mat:
        return cls.mask_bgr_in_hsv(roi_bgr, cls.ETR_HSV_MIN, cls.ETR_HSV_MAX)
    @classmethod
    def max_recall(cls, roi_bgr: Mat) -> Mat:
@ -99,32 +101,32 @@ class DeviceRoisMaskerAutoT1(DeviceRoisMaskerAuto):
    @classmethod
    def clear_status_track_lost(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(
-            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV),
+            roi_bgr,
            cls.TRACK_LOST_HSV_MIN,
            cls.TRACK_LOST_HSV_MAX,
        )
    @classmethod
    def clear_status_track_complete(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(
-            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV),
+            roi_bgr,
            cls.TRACK_COMPLETE_HSV_MIN,
            cls.TRACK_COMPLETE_HSV_MAX,
        )
    @classmethod
    def clear_status_full_recall(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(
-            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV),
+            roi_bgr,
            cls.FULL_RECALL_HSV_MIN,
            cls.FULL_RECALL_HSV_MAX,
        )
    @classmethod
    def clear_status_pure_memory(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(
-            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV),
+            roi_bgr,
            cls.PURE_MEMORY_HSV_MIN,
            cls.PURE_MEMORY_HSV_MAX,
        )
@ -132,10 +134,10 @@ class DeviceRoisMaskerAutoT1(DeviceRoisMaskerAuto):
 class DeviceRoisMaskerAutoT2(DeviceRoisMaskerAuto):
    PFL_HSV_MIN = np.array([0, 0, 248], np.uint8)
-    PFL_HSV_MAX = np.array([179, 10, 255], np.uint8)
+    PFL_HSV_MAX = np.array([179, 40, 255], np.uint8)
-    WHITE_HSV_MIN = np.array([0, 0, 240], np.uint8)
+    SCORE_HSV_MIN = np.array([0, 0, 180], np.uint8)
-    WHITE_HSV_MAX = np.array([179, 10, 255], np.uint8)
+    SCORE_HSV_MAX = np.array([179, 255, 255], np.uint8)
    PST_HSV_MIN = np.array([100, 50, 80], np.uint8)
    PST_HSV_MAX = np.array([100, 255, 255], np.uint8)
@ -149,6 +151,9 @@ class DeviceRoisMaskerAutoT2(DeviceRoisMaskerAuto):
    BYD_HSV_MIN = np.array([170, 50, 50], np.uint8)
    BYD_HSV_MAX = np.array([179, 210, 198], np.uint8)
    ETR_HSV_MIN = np.array([130, 60, 80], np.uint8)
    ETR_HSV_MAX = np.array([140, 145, 180], np.uint8)
    MAX_RECALL_HSV_MIN = np.array([125, 0, 0], np.uint8)
    MAX_RECALL_HSV_MAX = np.array([145, 100, 150], np.uint8)
@ -166,9 +171,7 @@ class DeviceRoisMaskerAutoT2(DeviceRoisMaskerAuto):
    @classmethod
    def pfl(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(roi_bgr, cls.PFL_HSV_MIN, cls.PFL_HSV_MAX)
            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV), cls.PFL_HSV_MIN, cls.PFL_HSV_MAX
        )
    @classmethod
    def pure(cls, roi_bgr: Mat) -> Mat:
@ -184,72 +187,64 @@ class DeviceRoisMaskerAutoT2(DeviceRoisMaskerAuto):
    @classmethod
    def score(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(roi_bgr, cls.SCORE_HSV_MIN, cls.SCORE_HSV_MAX)
            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV),
            cls.WHITE_HSV_MIN,
            cls.WHITE_HSV_MAX,
        )
    @classmethod
    def rating_class_pst(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(roi_bgr, cls.PST_HSV_MIN, cls.PST_HSV_MAX)
            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV), cls.PST_HSV_MIN, cls.PST_HSV_MAX
        )
    @classmethod
    def rating_class_prs(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(roi_bgr, cls.PRS_HSV_MIN, cls.PRS_HSV_MAX)
            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV), cls.PRS_HSV_MIN, cls.PRS_HSV_MAX
        )
    @classmethod
    def rating_class_ftr(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(roi_bgr, cls.FTR_HSV_MIN, cls.FTR_HSV_MAX)
            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV), cls.FTR_HSV_MIN, cls.FTR_HSV_MAX
        )
    @classmethod
    def rating_class_byd(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(roi_bgr, cls.BYD_HSV_MIN, cls.BYD_HSV_MAX)
-            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV), cls.BYD_HSV_MIN, cls.BYD_HSV_MAX
+
-        )
+    @classmethod
    def rating_class_etr(cls, roi_bgr: Mat) -> Mat:
        return cls.mask_bgr_in_hsv(roi_bgr, cls.ETR_HSV_MIN, cls.ETR_HSV_MAX)
    @classmethod
    def max_recall(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(
-            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV),
+            roi_bgr,
            cls.MAX_RECALL_HSV_MIN,
            cls.MAX_RECALL_HSV_MAX,
        )
    @classmethod
    def clear_status_track_lost(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(
-            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV),
+            roi_bgr,
            cls.TRACK_LOST_HSV_MIN,
            cls.TRACK_LOST_HSV_MAX,
        )
    @classmethod
    def clear_status_track_complete(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(
-            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV),
+            roi_bgr,
            cls.TRACK_COMPLETE_HSV_MIN,
            cls.TRACK_COMPLETE_HSV_MAX,
        )
    @classmethod
    def clear_status_full_recall(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(
-            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV),
+            roi_bgr,
            cls.FULL_RECALL_HSV_MIN,
            cls.FULL_RECALL_HSV_MAX,
        )
    @classmethod
    def clear_status_pure_memory(cls, roi_bgr: Mat) -> Mat:
-        return cv2.inRange(
+        return cls.mask_bgr_in_hsv(
-            cv2.cvtColor(roi_bgr, cv2.COLOR_BGR2HSV),
+            roi_bgr,
            cls.PURE_MEMORY_HSV_MIN,
            cls.PURE_MEMORY_HSV_MAX,
        )
--- a/src/arcaea_offline_ocr/scenarios/device/masker/base.py
+++ b/src/arcaea_offline_ocr/scenarios/device/masker/base.py
@ -0,0 +1,61 @@
 from abc import ABC, abstractmethod
 from arcaea_offline_ocr.types import Mat
 class DeviceRoisMasker(ABC):
    @classmethod
    @abstractmethod
    def pure(cls, roi_bgr: Mat) -> Mat: ...
    @classmethod
    @abstractmethod
    def far(cls, roi_bgr: Mat) -> Mat: ...
    @classmethod
    @abstractmethod
    def lost(cls, roi_bgr: Mat) -> Mat: ...
    @classmethod
    @abstractmethod
    def score(cls, roi_bgr: Mat) -> Mat: ...
    @classmethod
    @abstractmethod
    def rating_class_pst(cls, roi_bgr: Mat) -> Mat: ...
    @classmethod
    @abstractmethod
    def rating_class_prs(cls, roi_bgr: Mat) -> Mat: ...
    @classmethod
    @abstractmethod
    def rating_class_ftr(cls, roi_bgr: Mat) -> Mat: ...
    @classmethod
    @abstractmethod
    def rating_class_byd(cls, roi_bgr: Mat) -> Mat: ...
    @classmethod
    @abstractmethod
    def rating_class_etr(cls, roi_bgr: Mat) -> Mat: ...
    @classmethod
    @abstractmethod
    def max_recall(cls, roi_bgr: Mat) -> Mat: ...
    @classmethod
    @abstractmethod
    def clear_status_track_lost(cls, roi_bgr: Mat) -> Mat: ...
    @classmethod
    @abstractmethod
    def clear_status_track_complete(cls, roi_bgr: Mat) -> Mat: ...
    @classmethod
    @abstractmethod
    def clear_status_full_recall(cls, roi_bgr: Mat) -> Mat: ...
    @classmethod
    @abstractmethod
    def clear_status_pure_memory(cls, roi_bgr: Mat) -> Mat: ...
--- a/src/arcaea_offline_ocr/scenarios/device/rois/init.py
+++ b/src/arcaea_offline_ocr/scenarios/device/rois/init.py
@ -0,0 +1,9 @@
 from .auto import DeviceRoisAuto, DeviceRoisAutoT1, DeviceRoisAutoT2
 from .base import DeviceRois
 __all__ = [
    "DeviceRois",
    "DeviceRoisAuto",
    "DeviceRoisAutoT1",
    "DeviceRoisAutoT2",
 ]
--- a/src/arcaea_offline_ocr/device/rois/definition/auto.py
+++ b/src/arcaea_offline_ocr/device/rois/definition/auto.py
@ -1,6 +1,6 @@
-from .common import DeviceRois
+from arcaea_offline_ocr.types import XYWHRect
-__all__ = ["DeviceRoisAuto", "DeviceRoisAutoT1", "DeviceRoisAutoT2"]
+from .base import DeviceRois
 class DeviceRoisAuto(DeviceRois):
@ -50,7 +50,7 @@ class DeviceRoisAutoT1(DeviceRoisAuto):
    @property
    def pure(self):
-        return (
+        return XYWHRect(
            self.pfl_x,
            self.layout_area_h_mid + 110 * self.factor,
            self.pfl_w,
@ -59,7 +59,7 @@ class DeviceRoisAutoT1(DeviceRoisAuto):
    @property
    def far(self):
-        return (
+        return XYWHRect(
            self.pfl_x,
            self.pure[1] + self.pure[3] + 12 * self.factor,
            self.pfl_w,
@ -68,7 +68,7 @@ class DeviceRoisAutoT1(DeviceRoisAuto):
    @property
    def lost(self):
-        return (
+        return XYWHRect(
            self.pfl_x,
            self.far[1] + self.far[3] + 10 * self.factor,
            self.pfl_w,
@ -79,7 +79,7 @@ class DeviceRoisAutoT1(DeviceRoisAuto):
    def score(self):
        w = 280 * self.factor
        h = 45 * self.factor
-        return (
+        return XYWHRect(
            self.w_mid - w / 2,
            self.layout_area_h_mid - 75 * self.factor - h,
            w,
@ -88,7 +88,7 @@ class DeviceRoisAutoT1(DeviceRoisAuto):
    @property
    def rating_class(self):
-        return (
+        return XYWHRect(
            self.w_mid - 610 * self.factor,
            self.layout_area_h_mid - 180 * self.factor,
            265 * self.factor,
@ -97,7 +97,7 @@ class DeviceRoisAutoT1(DeviceRoisAuto):
    @property
    def max_recall(self):
-        return (
+        return XYWHRect(
            self.w_mid - 465 * self.factor,
            self.layout_area_h_mid - 215 * self.factor,
            150 * self.factor,
@ -106,7 +106,7 @@ class DeviceRoisAutoT1(DeviceRoisAuto):
    @property
    def jacket(self):
-        return (
+        return XYWHRect(
            self.w_mid - 610 * self.factor,
            self.layout_area_h_mid - 143 * self.factor,
            375 * self.factor,
@ -117,10 +117,10 @@ class DeviceRoisAutoT1(DeviceRoisAuto):
    def clear_status(self):
        w = 550 * self.factor
        h = 60 * self.factor
-        return (
+        return XYWHRect(
            self.w_mid - w / 2,
            self.layout_area_h_mid - 155 * self.factor - h,
-            w,
+            w * 0.4,
            h,
        )
@ -128,7 +128,7 @@ class DeviceRoisAutoT1(DeviceRoisAuto):
    def partner_icon(self):
        w = 90 * self.factor
        h = 75 * self.factor
-        return (self.w_mid - w / 2, 0, w, h)
+        return XYWHRect(self.w_mid - w / 2, 0, w, h)
 class DeviceRoisAutoT2(DeviceRoisAuto):
@ -174,7 +174,7 @@ class DeviceRoisAutoT2(DeviceRoisAuto):
    @property
    def pure(self):
-        return (
+        return XYWHRect(
            self.pfl_x,
            self.layout_area_h_mid + 175 * self.factor,
            self.pfl_w,
@ -183,7 +183,7 @@ class DeviceRoisAutoT2(DeviceRoisAuto):
    @property
    def far(self):
-        return (
+        return XYWHRect(
            self.pfl_x,
            self.pure[1] + self.pure[3] + 30 * self.factor,
            self.pfl_w,
@ -192,7 +192,7 @@ class DeviceRoisAutoT2(DeviceRoisAuto):
    @property
    def lost(self):
-        return (
+        return XYWHRect(
            self.pfl_x,
            self.far[1] + self.far[3] + 35 * self.factor,
            self.pfl_w,
@ -203,7 +203,7 @@ class DeviceRoisAutoT2(DeviceRoisAuto):
    def score(self):
        w = 420 * self.factor
        h = 70 * self.factor
-        return (
+        return XYWHRect(
            self.w_mid - w / 2,
            self.layout_area_h_mid - 110 * self.factor - h,
            w,
@ -212,7 +212,7 @@ class DeviceRoisAutoT2(DeviceRoisAuto):
    @property
    def rating_class(self):
-        return (
+        return XYWHRect(
            max(0, self.w_mid - 965 * self.factor),
            self.layout_area_h_mid - 330 * self.factor,
            350 * self.factor,
@ -221,7 +221,7 @@ class DeviceRoisAutoT2(DeviceRoisAuto):
    @property
    def max_recall(self):
-        return (
+        return XYWHRect(
            self.w_mid - 625 * self.factor,
            self.layout_area_h_mid - 275 * self.factor,
            150 * self.factor,
@ -230,7 +230,7 @@ class DeviceRoisAutoT2(DeviceRoisAuto):
    @property
    def jacket(self):
-        return (
+        return XYWHRect(
            self.w_mid - 915 * self.factor,
            self.layout_area_h_mid - 215 * self.factor,
            565 * self.factor,
@ -241,10 +241,10 @@ class DeviceRoisAutoT2(DeviceRoisAuto):
    def clear_status(self):
        w = 825 * self.factor
        h = 90 * self.factor
-        return (
+        return XYWHRect(
            self.w_mid - w / 2,
            self.layout_area_h_mid - 235 * self.factor - h,
-            w,
+            w * 0.4,
            h,
        )
@ -252,4 +252,4 @@ class DeviceRoisAutoT2(DeviceRoisAuto):
    def partner_icon(self):
        w = 135 * self.factor
        h = 110 * self.factor
-        return (self.w_mid - w / 2, 0, w, h)
+        return XYWHRect(self.w_mid - w / 2, 0, w, h)
--- a/src/arcaea_offline_ocr/scenarios/device/rois/base.py
+++ b/src/arcaea_offline_ocr/scenarios/device/rois/base.py
@ -0,0 +1,33 @@
 from abc import ABC, abstractmethod
 from arcaea_offline_ocr.types import XYWHRect
 class DeviceRois(ABC):
    @property
    @abstractmethod
    def pure(self) -> XYWHRect: ...
    @property
    @abstractmethod
    def far(self) -> XYWHRect: ...
    @property
    @abstractmethod
    def lost(self) -> XYWHRect: ...
    @property
    @abstractmethod
    def score(self) -> XYWHRect: ...
    @property
    @abstractmethod
    def rating_class(self) -> XYWHRect: ...
    @property
    @abstractmethod
    def max_recall(self) -> XYWHRect: ...
    @property
    @abstractmethod
    def jacket(self) -> XYWHRect: ...
    @property
    @abstractmethod
    def clear_status(self) -> XYWHRect: ...
    @property
    @abstractmethod
    def partner_icon(self) -> XYWHRect: ...
--- a/src/arcaea_offline_ocr/types.py
+++ b/src/arcaea_offline_ocr/types.py
@ -1,25 +1,42 @@
-from collections.abc import Iterable
+from math import floor
-from typing import NamedTuple, Tuple, Union
+from typing import Callable, NamedTuple, Union
 import numpy as np
 Mat = np.ndarray
 _IntOrFloat = Union[int, float]
 class XYWHRect(NamedTuple):
-    x: int
+    x: _IntOrFloat
-    y: int
+    y: _IntOrFloat
-    w: int
+    w: _IntOrFloat
-    h: int
+    h: _IntOrFloat
-    def __add__(self, other: Union["XYWHRect", Tuple[int, int, int, int]]):
+    def _to_int(self, func: Callable[[_IntOrFloat], int]):
-        if not isinstance(other, Iterable) or len(other) != 4:
+        return (func(self.x), func(self.y), func(self.w), func(self.h))
-            raise ValueError()
+
    def rounded(self):
        return self._to_int(round)
    def floored(self):
        return self._to_int(floor)
    def __add__(self, other):
        if not isinstance(other, (list, tuple)) or len(other) != 4:
            raise TypeError
        return self.__class__(*[a + b for a, b in zip(self, other)])
-    def __sub__(self, other: Union["XYWHRect", Tuple[int, int, int, int]]):
+    def __sub__(self, other):
-        if not isinstance(other, Iterable) or len(other) != 4:
+        if not isinstance(other, (list, tuple)) or len(other) != 4:
-            raise ValueError()
+            raise TypeError
        return self.__class__(*[a - b for a, b in zip(self, other)])
    def __mul__(self, other):
        if not isinstance(other, (int, float)):
            raise TypeError
        return self.__class__(*[v * other for v in self])
--- a/src/arcaea_offline_ocr/utils.py
+++ b/src/arcaea_offline_ocr/utils.py
@ -1,11 +1,6 @@
 from collections.abc import Iterable
 from typing import Callable, TypeVar, Union, overload
 import cv2
 import numpy as np
 from .types import XYWHRect
 __all__ = ["imread_unicode"]
@ -13,34 +8,3 @@ def imread_unicode(filepath: str, flags: int = cv2.IMREAD_UNCHANGED):
    # https://stackoverflow.com/a/57872297/16484891
    # CC BY-SA 4.0
    return cv2.imdecode(np.fromfile(filepath, dtype=np.uint8), flags)
 def construct_int_xywh_rect(
    rect: XYWHRect, func: Callable[[Union[int, float]], int] = round
 ):
    return XYWHRect(*[func(num) for num in rect])
@overload
 def apply_factor(item: int, factor: float) -> float:
    ...
@overload
 def apply_factor(item: float, factor: float) -> float:
    ...
 T = TypeVar("T", bound=Iterable)
@overload
 def apply_factor(item: T, factor: float) -> T:
    ...
 def apply_factor(item, factor: float):
    if isinstance(item, (int, float)):
        return item * factor
    elif isinstance(item, Iterable):
        return item.__class__([i * factor for i in item])
Author	SHA1	Message	Date
283375	8cc407b2bc	chore: update README	2025-06-27 02:06:24 +08:00
283375	673e45834d	chore: apply ruff rules	2025-06-27 01:38:54 +08:00
283375	57f430770e	chore: update dependencies	2025-06-27 01:06:24 +08:00
283375	d7ad85bdb0	ci: new build & publish workflow	2025-06-26 01:11:25 +08:00
283375	0b53682398	ci: fix tag condition - ok i didnt expect github actions does not support regex wtf	2025-06-26 00:15:02 +08:00
283375	b117346b46	chore: setuptools-scm integration	2025-06-26 00:07:08 +08:00
283375	ad0a33daad	ci: tag regex	2025-06-25 23:43:46 +08:00
283375	c08a1332a7	chore!: removing unused code	2025-06-25 23:37:21 +08:00
283375	0055d9e8da	refactor!: device scenario - Correct abstract class annotations	2025-06-25 23:35:38 +08:00
283375	06156db9c2	refactor!: chieri v4 b30 scenario - Remove useless `.utils` code	2025-06-25 23:27:15 +08:00
283375	c65798a02d	feat: XYWHRect `__mul__`	2025-06-25 23:19:52 +08:00
283375	f11dc6e38f	refactor: scenario base	2025-06-25 23:11:45 +08:00
283375	2b18906935	refactor!: image hash database provider	2025-06-22 01:28:59 +08:00
283375	abfd37dbef	refactor!: OCR text result provider	2025-06-22 00:32:31 +08:00
283375	3ebb058cdf	refactor: `XYWHRect` and b30 ocr	2025-06-21 16:06:49 +08:00
283375	b545c5b6bf	refactor!: `ImageHashType` -> `ImageHashCategory`	2025-06-17 22:28:16 +08:00
283375	212afa32db	chore: update dependencies	2025-06-17 18:13:59 +08:00
283375	2264e90b8e	refactor!: replace `attrs` with `dataclass`	2025-06-17 18:05:44 +08:00
283375	619bff2ea4	feat: image hashes database	2025-01-10 23:55:37 +08:00
283375	413188d86a	feat: core hashers	2025-01-10 23:54:37 +08:00
283375	cfe8de043c	chore: pre-commit hooks update	2025-01-10 23:54:00 +08:00
283375	3f6c08b2ad	fix: preprocess_char_icon copyMakeBorder edge case	2025-01-10 23:46:50 +08:00
283375	854d5558cf	chore: v0.0.99	2024-06-19 22:23:30 +08:00
283375	df77421a34	impr: DeviceRoisMaskerAutoT2 pfl color range (#11 )	2024-06-05 18:46:16 +08:00
283375	2241230a7a	chore: v0.0.98	2024-04-01 00:32:34 +08:00
283375	fb4b1fb9b8	ci: build package using github actions	2024-04-01 00:26:12 +08:00
283375	00cd32dfdc	feat: ETERNAL rating class support	2024-03-20 15:53:10 +08:00
283375	17f6c2bac7	chore: code linting	2023-11-04 15:28:10 +08:00
283375	76e6adbbf7	chore: v0.0.97	2023-11-01 14:41:22 +08:00
283375	288ccddfa1	chore: update README	2023-11-01 14:01:53 +08:00
283375	58d5022952	chore(Masker): add common method	2023-11-01 13:55:52 +08:00
283375	80404c436f	impr(Masker): expand score color range	2023-11-01 13:26:49 +08:00
283375	bdf748bc63	chore: .gitignore venv	2023-10-29 23:46:40 +08:00
Lzhyrifx	c864414b88	pre-commit (#9 ) clean up legacy code	2023-10-29 17:20:33 +08:00
283375	0fbd33645b	impr: `DeviceRoisAuto.clear_status` width	2023-10-28 22:22:04 +08:00
		`@ -0,0 +1,3 @@`
							`from .index import average, dct, difference`

							`__all__ = ["average", "dct", "difference"]`
		`@ -1,2 +0,0 @@`
			`from .common import DeviceOcrResult`
			`from .ocr import DeviceOcr`
		`@ -1,2 +0,0 @@`
			`from .auto import *`
			`from .common import DeviceRois`
		`@ -1,2 +0,0 @@`
			`from .auto import *`
			`from .common import DeviceRoisMasker`
		`@ -0,0 +1,3 @@`
							`from .chieri import ChieriBotV4Best30Scenario`

							`__all__ = ["ChieriBotV4Best30Scenario"]`
		`@ -0,0 +1,3 @@`
							`from .v4 import ChieriBotV4Best30Scenario`

							`__all__ = ["ChieriBotV4Best30Scenario"]`
		`@ -0,0 +1,3 @@`
							`from .impl import ChieriBotV4Best30Scenario`

							`__all__ = ["ChieriBotV4Best30Scenario"]`
		`@ -0,0 +1,3 @@`
							`from .base import DeviceRoisExtractor`

							`__all__ = ["DeviceRoisExtractor"]`