Add Reframr-RFM-v2-Base release files

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	import re
	import unicodedata
	from collections import Counter
	from collections.abc import Mapping
	from dataclasses import dataclass, field
	from string import ascii_letters, digits

	from .reasoning import REASONING_CONTROL_TOKENS, TOKENIZER_NAME

	PRETOKEN_PATTERN = re.compile(
	r"https?://[A-Za-z0-9_~:/?#\[\]@!$&'()+,;=%.-][A-Za-z0-9_~/#]"
	r"\|[^\W_]+(?:[._/-][^\W_]+)+"
	r"\|\w+\|[^\w\s]",
	re.UNICODE,
	)
	BYTE_FALLBACK_PATTERN = re.compile(r"<byte:([0-9A-F]{2})>")
	DEFAULT_FALLBACK_CHARACTERS = (
	ascii_letters
	+ digits
	+ "'-_/.:,;!?()[]{}@#$%&*+="
	+ "’ʼ‘“”—–…"
	)
	MAX_TOKENIZER_VOCAB_SIZE = 65536
	MAX_SEGMENT_CACHE_SIZE = 200_000
	MAX_TRAINED_PAIR_MERGES = 384
	MAX_PAIR_TRAINING_SEGMENTS = 4096


	def _is_word_character(character: str) -> bool:
	category = unicodedata.category(character)
	return character == "_" or category[0] in {"L", "N"} or category == "Mn"


	def _is_variation_selector(character: str) -> bool:
	return "VARIATION SELECTOR" in unicodedata.name(character, "")


	def _is_zero_width_joiner(character: str) -> bool:
	return unicodedata.name(character, "") == "ZERO WIDTH JOINER"


	def _is_emoji_modifier(character: str) -> bool:
	return "EMOJI MODIFIER" in unicodedata.name(character, "")


	def _is_emoji_base_character(character: str) -> bool:
	name = unicodedata.name(character, "")
	category = unicodedata.category(character)
	return (
	"EMOJI" in name
	or "REGIONAL INDICATOR SYMBOL" in name
	or (category in {"So", "Sk"} and ord(character) >= 0x2100)
	)


	def _is_emoji_continuation_character(character: str) -> bool:
	category = unicodedata.category(character)
	name = unicodedata.name(character, "")
	return (
	_is_variation_selector(character)
	or _is_zero_width_joiner(character)
	or _is_emoji_modifier(character)
	or category in {"Mn", "Me"}
	or name.startswith("TAG ")
	)


	def _consume_emoji_cluster(text: str, start: int) -> int:
	if start >= len(text) or not _is_emoji_base_character(text[start]):
	return start

	index = start + 1
	if "REGIONAL INDICATOR SYMBOL" in unicodedata.name(text[start], ""):
	if index < len(text) and "REGIONAL INDICATOR SYMBOL" in unicodedata.name(text[index], ""):
	return index + 1
	return index

	while index < len(text):
	if _is_emoji_continuation_character(text[index]):
	index += 1
	continue
	if _is_zero_width_joiner(text[index - 1]) and _is_emoji_base_character(text[index]):
	index += 1
	continue
	break
	return index


	def _byte_token(value: int) -> str:
	return f"<byte:{value:02X}>"


	def _byte_value(piece: str) -> int \| None:
	match = BYTE_FALLBACK_PATTERN.fullmatch(piece)
	if match is None:
	return None
	return int(match.group(1), 16)


	def _is_punctuation_piece(piece: str) -> bool:
	return bool(piece) and all(
	unicodedata.category(character).startswith("P")
	for character in piece
	)


	def _is_opening_punctuation(piece: str) -> bool:
	return bool(piece) and all(
	unicodedata.category(character) in {"Ps", "Pi"}
	for character in piece
	)


	def _is_call_opening_punctuation(piece: str) -> bool:
	return bool(piece) and all(
	unicodedata.category(character) == "Ps"
	and "PARENTHESIS" in unicodedata.name(character, "")
	for character in piece
	)


	def _is_closing_or_terminal_punctuation(piece: str) -> bool:
	return bool(piece) and all(
	unicodedata.category(character) in {"Pe", "Pf", "Po"}
	for character in piece
	)


	def _is_infix_joiner(piece: str) -> bool:
	if len(piece) != 1:
	return False
	category = unicodedata.category(piece)
	name = unicodedata.name(piece, "")
	return (
	category == "Pd"
	or "APOSTROPHE" in name
	or (category == "Pf" and "SINGLE QUOTATION MARK" in name)
	or "SOLIDUS" in name
	)


	def _joins_adjacent_digits(piece: str) -> bool:
	if len(piece) != 1:
	return False
	category = unicodedata.category(piece)
	name = unicodedata.name(piece, "")
	return category.startswith("P") and "COLON" in name


	def _is_dash_joiner(piece: str) -> bool:
	if len(piece) != 1:
	return False
	category = unicodedata.category(piece)
	name = unicodedata.name(piece, "")
	return category == "Pd" or "HYPHEN" in name or "DASH" in name


	def _is_quote_piece(piece: str) -> bool:
	if len(piece) != 1:
	return False
	if _is_infix_joiner(piece):
	return False
	name = unicodedata.name(piece, "")
	category = unicodedata.category(piece)
	return "QUOTATION MARK" in name or category in {"Pi", "Pf"}


	def _is_repeatable_delimiter_symbol(piece: str) -> bool:
	if len(piece) != 1:
	return False
	if _is_emoji_base_character(piece) or _is_emoji_continuation_character(piece):
	return False
	return unicodedata.category(piece).startswith("S")


	def _merge_symbol(left: str, right: str, prefix: str) -> str:
	if right.startswith(prefix):
	return left + right[len(prefix):]
	return left + right


	def _merge_sequence(symbols: list[str], pair: tuple[str, str], merged_symbol: str) -> list[str]:
	merged: list[str] = []
	index = 0
	while index < len(symbols):
	if index < len(symbols) - 1 and (symbols[index], symbols[index + 1]) == pair:
	merged.append(merged_symbol)
	index += 2
	else:
	merged.append(symbols[index])
	index += 1
	return merged


	def _default_symbol_inventory(word_prefix: str) -> set[str]:
	symbols: set[str] = set()
	for character in DEFAULT_FALLBACK_CHARACTERS:
	symbols.add(character)
	symbols.add(f"{word_prefix}{character}")
	for value in range(256):
	token = _byte_token(value)
	symbols.add(token)
	symbols.add(f"{word_prefix}{token}")
	return symbols


	def _pair_training_segment_items(
	word_counts: Mapping[str, float],
	*,
	min_pair_frequency: int,
	limit: int = MAX_PAIR_TRAINING_SEGMENTS,
	) -> list[tuple[str, float]]:
	candidates = [
	(str(segment), float(frequency))
	for segment, frequency in word_counts.items()
	if len(str(segment)) > 1 and float(frequency) >= min_pair_frequency
	]
	candidates.sort(
	key=lambda item: (
	-(item[1] * len(item[0])),
	-item[1],
	-len(item[0]),
	item[0],
	)
	)
	if limit > 0:
	return candidates[:limit]
	return candidates


	def _whole_segment_token(segment: str, word_prefix: str) -> str:
	return f"{word_prefix}{segment}"


	def recommend_vocab_size(
	text: str,
	*,
	minimum: int = 768,
	maximum: int = 1536,
	multiplier: int = 5,
	lowercase: bool = False,
	) -> int:
	seed_tokenizer = NativeTokenizer(
	merges=[],
	vocab=[],
	base_symbols=[],
	lowercase=lowercase,
	)
	segments = seed_tokenizer.pretokenize(text)
	distinct_segments = len(set(segments))
	recommended = max(minimum, distinct_segments * multiplier)
	return min(maximum, recommended)


	def clamp_vocab_size(requested: int, *, maximum: int = MAX_TOKENIZER_VOCAB_SIZE) -> int:
	return min(maximum, max(1, requested))


	@dataclass(slots=True)
	class NativeTokenizer:
	merges: list[tuple[str, str]]
	vocab: list[str]
	base_symbols: list[str]
	name: str = TOKENIZER_NAME
	lowercase: bool = False
	word_prefix: str = "▁"
	unk_token: str = "<unk>"
	bos_token: str = "<bos>"
	eos_token: str = "<eos>"
	pad_token: str = "<pad>"
	_merge_ranks: dict[tuple[str, str], int] = field(init=False, repr=False)
	_vocab_set: set[str] = field(init=False, repr=False)
	_base_symbol_set: set[str] = field(init=False, repr=False)
	_special_tokens: set[str] = field(init=False, repr=False)
	_pretoken_pattern: re.Pattern[str] = field(init=False, repr=False)
	_segment_cache: dict[str, tuple[str, ...]] = field(init=False, repr=False)

	def __post_init__(self) -> None:
	self._special_tokens = {
	self.unk_token,
	self.bos_token,
	self.eos_token,
	self.pad_token,
	*REASONING_CONTROL_TOKENS,
	}
	self._merge_ranks = {pair: index for index, pair in enumerate(self.merges)}
	self._base_symbol_set = set(self.base_symbols)
	self._vocab_set = set(self.vocab) \| self.special_tokens \| self._base_symbol_set
	self.vocab = sorted(self._vocab_set)
	self._pretoken_pattern = self._build_pretoken_pattern()
	self._segment_cache = {}

	@property
	def special_tokens(self) -> set[str]:
	return self._special_tokens

	@property
	def vocab_size(self) -> int:
	return len(self._vocab_set)

	def normalize(self, text: str) -> str:
	normalized = unicodedata.normalize("NFKC", text)
	return normalized.lower() if self.lowercase else normalized

	def pretokenize(self, text: str) -> list[str]:
	normalized = self.normalize(text)
	segments: list[str] = []
	reserved = sorted(self.special_tokens, key=len, reverse=True)
	index = 0
	while index < len(normalized):
	if normalized[index].isspace():
	if normalized[index] == "\r":
	if index + 1 < len(normalized) and normalized[index + 1] == "\n":
	segments.append("\n")
	index += 2
	continue
	segments.append("\n")
	index += 1
	continue
	if normalized[index] == "\n":
	segments.append("\n")
	index += 1
	continue
	whitespace_start = index
	while (
	index < len(normalized)
	and normalized[index].isspace()
	and normalized[index] not in {"\r", "\n"}
	):
	index += 1
	next_character = normalized[index] if index < len(normalized) else ""
	if segments and (
	segments[-1] == "\n"
	or _is_opening_punctuation(next_character)
	or _is_repeatable_delimiter_symbol(next_character)
	):
	segments.append(normalized[whitespace_start:index])
	continue

	matched_special = next(
	(
	token
	for token in reserved
	if normalized.startswith(token, index)
	),
	None,
	)
	if matched_special is not None:
	segments.append(matched_special)
	index += len(matched_special)
	continue

	emoji_end = _consume_emoji_cluster(normalized, index)
	if emoji_end > index:
	segments.append(normalized[index:emoji_end])
	index = emoji_end
	continue

	match = self._pretoken_pattern.match(normalized, index)
	if match is not None:
	segments.append(match.group(0))
	index = match.end()
	continue

	segments.append(normalized[index])
	index += 1
	return segments

	def encode(self, text: str, *, add_special_tokens: bool = False) -> list[str]:
	tokens: list[str] = []
	if add_special_tokens:
	tokens.append(self.bos_token)

	for segment in self.pretokenize(text):
	tokens.extend(self._encode_segment_cached(segment))

	if add_special_tokens:
	tokens.append(self.eos_token)

	if not tokens and text.strip():
	return [self.unk_token]
	return tokens

	def encode_many(
	self,
	texts: list[str] \| tuple[str, ...],
	*,
	add_special_tokens: bool = False,
	) -> list[list[str]]:
	return [
	self.encode(text, add_special_tokens=add_special_tokens)
	for text in texts
	]

	def decode(
	self,
	tokens: list[str],
	*,
	preserve_special_tokens: tuple[str, ...] = (),
	) -> str:
	text = ""
	join_next = False
	byte_buffer = bytearray()
	byte_starts_segment = False
	preserved_specials = set(preserve_special_tokens)

	def next_rendered_piece(start_index: int) -> str \| None:
	for raw_token in tokens[start_index:]:
	if raw_token in self.special_tokens:
	if raw_token in preserved_specials:
	return raw_token
	continue
	raw_starts_segment = raw_token.startswith(self.word_prefix)
	raw_piece = raw_token[len(self.word_prefix) :] if raw_starts_segment else raw_token
	if not raw_piece:
	continue
	if _byte_value(raw_piece) is not None:
	return None
	return raw_piece
	return None

	def append_piece(piece: str, starts_segment: bool, next_piece: str \| None = None) -> None:
	nonlocal text, join_next

	if piece == "\n":
	text = text.rstrip(" ")
	text += "\n"
	join_next = True
	return

	if piece.isspace():
	text += piece
	join_next = True
	return

	had_text_before_piece = bool(text.strip())
	previous_before_piece = text.rstrip(" ")[-1:] if text.strip(" ") else ""
	if _is_quote_piece(piece):
	quote_count = sum(1 for character in text if _is_quote_piece(character))
	opens_quote = quote_count % 2 == 0
	if opens_quote:
	if text and not text.endswith((" ", "\n")) and previous_before_piece not in {"(", "[", "{"}:
	text += " "
	text += piece
	join_next = True
	return
	text = text.rstrip(" ")
	text += piece
	join_next = False
	return

	continues_repeated_delimiter = _is_repeatable_delimiter_symbol(piece) and (
	previous_before_piece == piece or next_piece == piece
	)
	attaches_left = _is_closing_or_terminal_punctuation(piece) or _is_infix_joiner(piece)
	continues_segment = (not starts_segment) and any(
	_is_word_character(character) or _is_emoji_continuation_character(character)
	for character in piece
	)
	if starts_segment:
	if text and not join_next and not continues_repeated_delimiter:
	attaches_to_previous_code_span = (
	_is_opening_punctuation(piece)
	and previous_before_piece.isalnum()
	and next_piece is not None
	and (
	_is_infix_joiner(next_piece)
	or _is_call_opening_punctuation(piece)
	or any(_is_word_character(character) for character in next_piece)
	)
	)
	if not _is_punctuation_piece(piece) or (
	_is_opening_punctuation(piece)
	and not attaches_to_previous_code_span
	):
	text += " "
	text += piece
	else:
	if text and not join_next and not attaches_left and not continues_segment:
	text += " "
	text += piece

	join_next = (
	_is_infix_joiner(piece)
	and (
	not starts_segment
	or (
	had_text_before_piece
	and (
	not _is_dash_joiner(piece)
	or previous_before_piece.isalnum()
	or _is_opening_punctuation(previous_before_piece)
	)
	)
	)
	) or (
	_joins_adjacent_digits(piece)
	and previous_before_piece.isdigit()
	and bool(next_piece)
	and next_piece[:1].isdigit()
	) or _is_opening_punctuation(piece)
	if continues_repeated_delimiter:
	join_next = True

	def flush_bytes() -> None:
	nonlocal byte_buffer, byte_starts_segment
	if not byte_buffer:
	return
	append_piece(bytes(byte_buffer).decode("utf-8", errors="replace"), byte_starts_segment)
	byte_buffer = bytearray()
	byte_starts_segment = False

	for token_index, token in enumerate(tokens):
	if token in self.special_tokens:
	if token in preserved_specials:
	flush_bytes()
	if text and not text.endswith((" ", "\n")):
	text += " "
	text += token
	join_next = False
	continue
	starts_segment = token.startswith(self.word_prefix)
	piece = token[len(self.word_prefix) :] if starts_segment else token
	if not piece:
	continue
	byte_value = _byte_value(piece)
	if byte_value is not None:
	if not byte_buffer:
	byte_starts_segment = starts_segment
	byte_buffer.append(byte_value)
	continue

	flush_bytes()
	append_piece(piece, starts_segment, next_rendered_piece(token_index + 1))
	flush_bytes()
	return text.strip()

	def _encode_segment_cached(self, segment: str) -> tuple[str, ...]:
	cached = self._segment_cache.get(segment)
	if cached is not None:
	return cached
	encoded = tuple(self._encode_segment(segment))
	if len(self._segment_cache) < MAX_SEGMENT_CACHE_SIZE:
	self._segment_cache[segment] = encoded
	return encoded

	def _encode_segment(self, segment: str) -> list[str]:
	if segment in self.special_tokens:
	return [segment]
	whole_segment = _whole_segment_token(segment, self.word_prefix)
	if whole_segment in self._vocab_set:
	return [whole_segment]
	symbols = self._seed_symbols(segment)
	if not symbols:
	return []

	while len(symbols) > 1:
	best_rank: int \| None = None
	best_pair: tuple[str, str] \| None = None
	for index in range(len(symbols) - 1):
	pair = (symbols[index], symbols[index + 1])
	rank = self._merge_ranks.get(pair)
	if rank is None:
	continue
	if best_rank is None or rank < best_rank:
	best_rank = rank
	best_pair = pair
	if best_pair is None:
	break

	merged_symbol = _merge_symbol(best_pair[0], best_pair[1], self.word_prefix)
	symbols = _merge_sequence(symbols, best_pair, merged_symbol)

	if any(symbol not in self._vocab_set for symbol in symbols):
	return [self.unk_token]
	return symbols

	def _seed_symbols(self, segment: str) -> list[str]:
	symbols: list[str] = []
	for index, character in enumerate(segment):
	symbol = f"{self.word_prefix}{character}" if index == 0 else character
	if symbol in self._base_symbol_set:
	symbols.append(symbol)
	continue

	encoded = character.encode("utf-8")
	for byte_index, value in enumerate(encoded):
	token = _byte_token(value)
	if index == 0 and byte_index == 0:
	token = f"{self.word_prefix}{token}"
	symbols.append(token)

	if any(symbol not in self._base_symbol_set for symbol in symbols):
	return [self.unk_token]
	return symbols

	def to_dict(self) -> dict[str, object]:
	return {
	"name": self.name,
	"merges": [[left, right] for left, right in self.merges],
	"vocab": self.vocab,
	"base_symbols": self.base_symbols,
	"lowercase": self.lowercase,
	"word_prefix": self.word_prefix,
	"unk_token": self.unk_token,
	"bos_token": self.bos_token,
	"eos_token": self.eos_token,
	"pad_token": self.pad_token,
	}

	@classmethod
	def from_dict(cls, payload: dict[str, object]) -> "NativeTokenizer":
	return cls(
	merges=[(str(left), str(right)) for left, right in payload["merges"]],
	vocab=[str(token) for token in payload["vocab"]],
	base_symbols=[str(token) for token in payload["base_symbols"]],
	name=str(payload.get("name", TOKENIZER_NAME)),
	lowercase=bool(payload["lowercase"]),
	word_prefix=str(payload["word_prefix"]),
	unk_token=str(payload["unk_token"]),
	bos_token=str(payload["bos_token"]),
	eos_token=str(payload["eos_token"]),
	pad_token=str(payload["pad_token"]),
	)

	def _build_pretoken_pattern(self) -> re.Pattern[str]:
	reserved = sorted(self.special_tokens, key=len, reverse=True)
	if not reserved:
	return PRETOKEN_PATTERN
	reserved_pattern = "\|".join(re.escape(token) for token in reserved)
	return re.compile(f"{reserved_pattern}\|{PRETOKEN_PATTERN.pattern}", re.UNICODE)

	@classmethod
	def train(
	cls,
	text: str,
	*,
	vocab_size: int = 256,
	min_pair_frequency: int = 2,
	lowercase: bool = False,
	word_prefix: str = "▁",
	) -> "NativeTokenizer":
	seed_tokenizer = cls(
	merges=[],
	vocab=[],
	base_symbols=[],
	lowercase=lowercase,
	word_prefix=word_prefix,
	)
	segments = seed_tokenizer.pretokenize(text)
	if not segments:
	raise ValueError("Cannot train the native tokenizer on empty text.")

	return cls.train_from_segment_counts(
	Counter(segments),
	vocab_size=vocab_size,
	min_pair_frequency=min_pair_frequency,
	lowercase=lowercase,
	word_prefix=word_prefix,
	)

	@classmethod
	def train_from_segment_counts(
	cls,
	segment_counts: Mapping[str, float],
	*,
	vocab_size: int = 256,
	min_pair_frequency: int = 2,
	lowercase: bool = False,
	word_prefix: str = "▁",
	) -> "NativeTokenizer":
	if not segment_counts:
	raise ValueError("Cannot train the native tokenizer on empty segment counts.")
	seed_tokenizer = cls(
	merges=[],
	vocab=[],
	base_symbols=[],
	lowercase=lowercase,
	word_prefix=word_prefix,
	)

	word_counts = Counter(
	{
	str(segment): float(frequency)
	for segment, frequency in segment_counts.items()
	if str(segment) and float(frequency) > 0.0
	}
	)
	if not word_counts:
	raise ValueError("Cannot train the native tokenizer on empty segment counts.")
	observed_symbols = {
	f"{word_prefix}{character}" if index == 0 else character
	for segment in word_counts
	for index, character in enumerate(segment)
	}
	base_symbols = _default_symbol_inventory(word_prefix)
	base_symbols.update(observed_symbols)
	pair_training_segments = dict(
	_pair_training_segment_items(
	word_counts,
	min_pair_frequency=min_pair_frequency,
	limit=MAX_PAIR_TRAINING_SEGMENTS,
	)
	)
	sequences = {
	segment: [
	f"{word_prefix}{character}" if index == 0 else character
	for index, character in enumerate(segment)
	]
	for segment in pair_training_segments
	}
	vocab = set(observed_symbols) \| seed_tokenizer.special_tokens
	target_vocab_size = len(vocab) + max(1, vocab_size)
	segment_candidates = sorted(
	{
	segment
	for segment, frequency in word_counts.items()
	if len(segment) > 1 and frequency >= min_pair_frequency
	},
	key=lambda segment: (
	-(word_counts[segment] * len(segment)),
	-len(segment),
	segment,
	),
	)
	for segment in segment_candidates:
	if len(vocab) >= target_vocab_size:
	break
	vocab.add(_whole_segment_token(segment, word_prefix))
	merges: list[tuple[str, str]] = []

	while len(vocab) < target_vocab_size and len(merges) < MAX_TRAINED_PAIR_MERGES:
	pair_counts: Counter[tuple[str, str]] = Counter()
	for segment, frequency in pair_training_segments.items():
	symbols = sequences[segment]
	for index in range(len(symbols) - 1):
	pair_counts[(symbols[index], symbols[index + 1])] += frequency

	if not pair_counts:
	break

	best_pair, best_count = min(
	pair_counts.items(),
	key=lambda item: (-item[1], item[0][0], item[0][1]),
	)
	if best_count < min_pair_frequency:
	break

	merged_symbol = _merge_symbol(best_pair[0], best_pair[1], word_prefix)
	merges.append(best_pair)
	vocab.add(merged_symbol)
	for segment in sequences:
	sequences[segment] = _merge_sequence(sequences[segment], best_pair, merged_symbol)

	return cls(
	merges=merges,
	vocab=sorted(vocab),
	base_symbols=sorted(base_symbols),
	lowercase=lowercase,
	word_prefix=word_prefix,
	)