from typing import List, Tuple, Dict, Callable def preparse_loras_multipliers(loras_multipliers): if isinstance(loras_multipliers, list): return [multi.strip(" \r\n") if isinstance(multi, str) else multi for multi in loras_multipliers] loras_multipliers = loras_multipliers.strip(" \r\n") loras_mult_choices_list = loras_multipliers.replace("\r", "").split("\n") loras_mult_choices_list = [multi.strip() for multi in loras_mult_choices_list if len(multi)>0 and not multi.startswith("#")] loras_multipliers = " ".join(loras_mult_choices_list) return loras_multipliers.replace("|"," ").split(" ") def expand_slist(slists_dict, mult_no, num_inference_steps, model_switch_step, model_switch_step2 ): def expand_one(slist, num_inference_steps): if not isinstance(slist, list): slist = [slist] new_slist= [] if num_inference_steps <=0: return new_slist inc = len(slist) / num_inference_steps pos = 0 for i in range(num_inference_steps): new_slist.append(slist[ int(pos)]) pos += inc return new_slist phase1 = slists_dict["phase1"][mult_no] phase2 = slists_dict["phase2"][mult_no] phase3 = slists_dict["phase3"][mult_no] shared = slists_dict["shared"][mult_no] if shared: if isinstance(phase1, float): return phase1 return expand_one(phase1, num_inference_steps) else: if isinstance(phase1, float) and isinstance(phase2, float) and isinstance(phase3, float) and phase1 == phase2 and phase2 == phase3: return phase1 return expand_one(phase1, model_switch_step) + expand_one(phase2, model_switch_step2 - model_switch_step) + expand_one(phase3, num_inference_steps - model_switch_step2) def parse_loras_multipliers(loras_multipliers, nb_loras, num_inference_steps, merge_slist = None, nb_phases = 2, model_switch_step = None, model_switch_step2 = None): if "|" in loras_multipliers: pos = loras_multipliers.find("|") if "|" in loras_multipliers[pos+1:]: return "", "", "There can be only one '|' character in Loras Multipliers Sequence" if model_switch_step is None: model_switch_step = num_inference_steps if model_switch_step2 is None: model_switch_step2 = num_inference_steps def is_float(element: any) -> bool: if element is None: return False try: float(element) return True except ValueError: return False loras_list_mult_choices_nums = [] slists_dict = { "model_switch_step": model_switch_step} slists_dict = { "model_switch_step2": model_switch_step2} slists_dict["phase1"] = phase1 = [1.] * nb_loras slists_dict["phase2"] = phase2 = [1.] * nb_loras slists_dict["phase3"] = phase3 = [1.] * nb_loras slists_dict["shared"] = shared = [False] * nb_loras if isinstance(loras_multipliers, list) or len(loras_multipliers) > 0: list_mult_choices_list = preparse_loras_multipliers(loras_multipliers)[:nb_loras] for i, mult in enumerate(list_mult_choices_list): current_phase = phase1 if isinstance(mult, str): mult = mult.strip() phase_mult = mult.split(";") shared_phases = len(phase_mult) <=1 if not shared_phases and len(phase_mult) != nb_phases : return "", "", f"if the ';' syntax is used for one Lora multiplier, the multipliers for its {nb_phases} denoising phases should be specified for this multiplier" for phase_no, mult in enumerate(phase_mult): if phase_no == 1: current_phase = phase2 elif phase_no == 2: current_phase = phase3 if "," in mult: multlist = mult.split(",") slist = [] for smult in multlist: if not is_float(smult): return "", "", f"Lora sub value no {i+1} ({smult}) in Multiplier definition '{multlist}' is invalid in Phase {phase_no+1}" slist.append(float(smult)) else: if not is_float(mult): return "", "", f"Lora Multiplier no {i+1} ({mult}) is invalid" slist = float(mult) if shared_phases: phase1[i] = phase2[i] = phase3[i] = slist shared[i] = True else: current_phase[i] = slist else: phase1[i] = phase2[i] = phase3[i] = float(mult) shared[i] = True if merge_slist is not None: slists_dict["phase1"] = phase1 = merge_slist["phase1"] + phase1 slists_dict["phase2"] = phase2 = merge_slist["phase2"] + phase2 slists_dict["phase3"] = phase3 = merge_slist["phase3"] + phase3 slists_dict["shared"] = shared = merge_slist["shared"] + shared loras_list_mult_choices_nums = [ expand_slist(slists_dict, i, num_inference_steps, model_switch_step, model_switch_step2 ) for i in range(len(phase1)) ] loras_list_mult_choices_nums = [ slist[0] if isinstance(slist, list) else slist for slist in loras_list_mult_choices_nums ] return loras_list_mult_choices_nums, slists_dict, "" def update_loras_slists(trans, slists_dict, num_inference_steps, phase_switch_step = None, phase_switch_step2 = None): from mmgp import offload sz = len(slists_dict["phase1"]) slists = [ expand_slist(slists_dict, i, num_inference_steps, phase_switch_step, phase_switch_step2 ) for i in range(sz) ] nos = [str(l) for l in range(sz)] offload.activate_loras(trans, nos, slists ) def get_model_switch_steps(timesteps, guide_phases, model_switch_phase, switch_threshold, switch2_threshold ): total_num_steps = len(timesteps) model_switch_step = model_switch_step2 = None for i, t in enumerate(timesteps): if guide_phases >=2 and model_switch_step is None and t <= switch_threshold: model_switch_step = i if guide_phases >=3 and model_switch_step2 is None and t <= switch2_threshold: model_switch_step2 = i if model_switch_step is None: model_switch_step = total_num_steps if model_switch_step2 is None: model_switch_step2 = total_num_steps phases_description = "" if guide_phases > 1: phases_description = "Denoising Steps: " phases_description += f" Phase 1 = None" if model_switch_step == 0 else f" Phase 1 = 1:{ min(model_switch_step,total_num_steps) }" if model_switch_step < total_num_steps: phases_description += f", Phase 2 = None" if model_switch_step == model_switch_step2 else f", Phase 2 = {model_switch_step +1}:{ min(model_switch_step2,total_num_steps) }" if guide_phases > 2 and model_switch_step2 < total_num_steps: phases_description += f", Phase 3 = {model_switch_step2 +1}:{ total_num_steps}" return model_switch_step, model_switch_step2, phases_description from typing import List, Tuple, Dict, Callable _ALWD = set(":;,.0123456789") # ---------------- core parsing helpers ---------------- def _find_bar(s: str) -> int: com = False for i, ch in enumerate(s): if ch in ('\n', '\r'): com = False elif ch == '#': com = True elif ch == '|' and not com: return i return -1 def _spans(text: str) -> List[Tuple[int, int]]: res, com, in_tok, st = [], False, False, 0 for i, ch in enumerate(text): if ch in ('\n', '\r'): if in_tok: res.append((st, i)); in_tok = False com = False elif ch == '#': if in_tok: res.append((st, i)); in_tok = False com = True elif not com: if ch in _ALWD: if not in_tok: in_tok, st = True, i else: if in_tok: res.append((st, i)); in_tok = False if in_tok: res.append((st, len(text))) return res def _choose_sep(text: str, spans: List[Tuple[int, int]]) -> str: if len(spans) >= 2: a, b = spans[-2][1], spans[-1][0] return '\n' if ('\n' in text[a:b] or '\r' in text[a:b]) else ' ' return '\n' if ('\n' in text or '\r' in text) else ' ' def _ends_in_comment_line(text: str) -> bool: ln = text.rfind('\n') seg = text[ln + 1:] if ln != -1 else text return '#' in seg def _append_tokens(text: str, k: int, sep: str) -> str: if k <= 0: return text t = text if _ends_in_comment_line(t) and (not t.endswith('\n')): t += '\n' parts = [] if t and not t[-1].isspace(): parts.append(sep) parts.append('1') for _ in range(k - 1): parts.append(sep); parts.append('1') return t + ''.join(parts) def _erase_span_and_one_sep(text: str, st: int, en: int) -> str: n = len(text) r = en while r < n and text[r] in (' ', '\t'): r += 1 if r > en: return text[:st] + text[r:] l = st while l > 0 and text[l-1] in (' ', '\t'): l -= 1 if l < st: return text[:l] + text[en:] return text[:st] + text[en:] def _trim_last_tokens(text: str, spans: List[Tuple[int, int]], drop: int) -> str: if drop <= 0: return text new_text = text for st, en in reversed(spans[-drop:]): new_text = _erase_span_and_one_sep(new_text, st, en) while new_text and new_text[-1] in (' ', '\t'): new_text = new_text[:-1] return new_text def _enforce_count(text: str, target: int) -> str: sp = _spans(text); cur = len(sp) if cur == target: return text if cur > target: return _trim_last_tokens(text, sp, cur - target) sep = _choose_sep(text, sp) return _append_tokens(text, target - cur, sep) def _strip_bars_outside_comments(s: str) -> str: com, out = False, [] for ch in s: if ch in ('\n', '\r'): com = False; out.append(ch) elif ch == '#': com = True; out.append(ch) elif ch == '|' and not com: continue else: out.append(ch) return ''.join(out) def _replace_tokens(text: str, repl: Dict[int, str]) -> str: if not repl: return text sp = _spans(text) for idx in sorted(repl.keys(), reverse=True): if 0 <= idx < len(sp): st, en = sp[idx] text = text[:st] + repl[idx] + text[en:] return text def _drop_tokens_by_indices(text: str, idxs: List[int]) -> str: if not idxs: return text out = text for idx in sorted(set(idxs), reverse=True): sp = _spans(out) # recompute spans after each deletion if 0 <= idx < len(sp): st, en = sp[idx] out = _erase_span_and_one_sep(out, st, en) return out # ---------------- identity for dedupe ---------------- def _default_path_key(p: str) -> str: s = p.strip().replace('\\', '/') while '//' in s: s = s.replace('//', '/') if len(s) > 1 and s.endswith('/'): s = s[:-1] return s # ---------------- new-set splitter (FIX) ---------------- def _select_new_side( loras_new: List[str], mult_new: str, mode: str, # "merge before" | "merge after" ) -> Tuple[List[str], str]: """ Split mult_new on '|' (outside comments) and split loras_new accordingly. Return ONLY the side relevant to `mode`. Extras loras (if any) are appended to the selected side. """ bi = _find_bar(mult_new) if bi == -1: return loras_new, _strip_bars_outside_comments(mult_new) left, right = mult_new[:bi], mult_new[bi + 1:] nL, nR = len(_spans(left)), len(_spans(right)) L = len(loras_new) # Primary allocation by token counts b_count = min(nL, L) rem = max(0, L - b_count) a_count = min(nR, rem) extras = max(0, L - (b_count + a_count)) if mode == "merge before": # take BEFORE loras + extras l_sel = loras_new[:b_count] + (loras_new[b_count + a_count : b_count + a_count + extras] if extras else []) m_sel = left else: # take AFTER loras + extras start_after = b_count l_sel = loras_new[start_after:start_after + a_count] + (loras_new[start_after + a_count : start_after + a_count + extras] if extras else []) m_sel = right return l_sel, _strip_bars_outside_comments(m_sel) # ---------------- public API ---------------- def merge_loras_settings( loras_old: List[str], mult_old: str, loras_new: List[str], mult_new: str, mode: str = "merge before", path_key: Callable[[str], str] = _default_path_key, ) -> Tuple[List[str], str]: """ Merge settings with full formatting/comment preservation and correct handling of `mult_new` with '|'. Dedup rule: when merging AFTER (resp. BEFORE), if a new lora already exists in preserved BEFORE (resp. AFTER), update that preserved multiplier and drop the duplicate from the replaced side. """ assert mode in ("merge before", "merge after") # Old split & alignment bi_old = _find_bar(mult_old) before_old, after_old = (mult_old[:bi_old], mult_old[bi_old + 1:]) if bi_old != -1 else ("", mult_old) orig_had_bar = (bi_old != -1) sp_b_old, sp_a_old = _spans(before_old), _spans(after_old) n_b_old = len(sp_b_old) total_old = len(loras_old) if n_b_old <= total_old: keep_b = n_b_old keep_a = total_old - keep_b before_old_aligned = before_old after_old_aligned = _enforce_count(after_old, keep_a) else: keep_b = total_old keep_a = 0 before_old_aligned = _enforce_count(before_old, keep_b) after_old_aligned = _enforce_count(after_old, 0) # NEW: choose the relevant side of the *new* set (fix for '|' in mult_new) loras_new_sel, mult_new_sel = _select_new_side(loras_new, mult_new, mode) mult_new_aligned = _enforce_count(mult_new_sel, len(loras_new_sel)) sp_new = _spans(mult_new_aligned) new_tokens = [mult_new_aligned[st:en] for st, en in sp_new] if mode == "merge after": # Preserve BEFORE; replace AFTER (with dedupe/update) preserved_loras = loras_old[:keep_b] preserved_text = before_old_aligned preserved_spans = _spans(preserved_text) pos_by_key: Dict[str, int] = {} for i, lp in enumerate(preserved_loras): k = path_key(lp) if k not in pos_by_key: pos_by_key[k] = i repl_map: Dict[int, str] = {} drop_idxs: List[int] = [] for i, lp in enumerate(loras_new_sel): j = pos_by_key.get(path_key(lp)) if j is not None and j < len(preserved_spans): repl_map[j] = new_tokens[i] if i < len(new_tokens) else "1" drop_idxs.append(i) before_text = _replace_tokens(preserved_text, repl_map) after_text = _drop_tokens_by_indices(mult_new_aligned, drop_idxs) loras_keep = [lp for i, lp in enumerate(loras_new_sel) if i not in set(drop_idxs)] loras_out = preserved_loras + loras_keep else: # Preserve AFTER; replace BEFORE (with dedupe/update) preserved_loras = loras_old[keep_b:] preserved_text = after_old_aligned preserved_spans = _spans(preserved_text) pos_by_key: Dict[str, int] = {} for i, lp in enumerate(preserved_loras): k = path_key(lp) if k not in pos_by_key: pos_by_key[k] = i repl_map: Dict[int, str] = {} drop_idxs: List[int] = [] for i, lp in enumerate(loras_new_sel): j = pos_by_key.get(path_key(lp)) if j is not None and j < len(preserved_spans): repl_map[j] = new_tokens[i] if i < len(new_tokens) else "1" drop_idxs.append(i) after_text = _replace_tokens(preserved_text, repl_map) before_text = _drop_tokens_by_indices(mult_new_aligned, drop_idxs) loras_keep = [lp for i, lp in enumerate(loras_new_sel) if i not in set(drop_idxs)] loras_out = loras_keep + preserved_loras # Compose, preserving explicit "before-only" bar when appropriate has_before = len(_spans(before_text)) > 0 has_after = len(_spans(after_text)) > 0 if has_before and has_after: mult_out = f"{before_text}|{after_text}" elif has_before: mult_out = before_text + ('|' if (mode == 'merge before' or orig_had_bar) else '') else: mult_out = after_text return loras_out, mult_out # ---------------- extractor ---------------- def extract_loras_side( loras: List[str], mult: str, which: str = "before", ) -> Tuple[List[str], str]: assert which in ("before", "after") bi = _find_bar(mult) before_txt, after_txt = (mult[:bi], mult[bi + 1:]) if bi != -1 else ("", mult) sp_b = _spans(before_txt) n_b = len(sp_b) total = len(loras) if n_b <= total: keep_b = n_b keep_a = total - keep_b else: keep_b = total keep_a = 0 if which == "before": return loras[:keep_b], _enforce_count(before_txt, keep_b) else: return loras[keep_b:keep_b + keep_a], _enforce_count(after_txt, keep_a)