mirror of
https://github.com/ggerganov/llama.cpp.git
synced 2024-10-30 06:30:15 +01:00
cbef542879
- use f-strings where possible - drop first param of encode/decode functions since "utf-8" is the default
275 lines
8.9 KiB
Python
275 lines
8.9 KiB
Python
# Convert a LLaMA model checkpoint to a ggjt compatible file
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#
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# Load the model using Torch
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# Iterate over all variables and write them to a binary file.
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#
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# For each variable, write the following:
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# - Number of dimensions (int)
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# - Name length (int)
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# - Dimensions (int[n_dims])
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# - Name (char[name_length])
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# - Data (float[n_dims])
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#
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# At the start of the ggml file we write the model parameters
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# and vocabulary.
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#
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import argparse
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import os
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import sys
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import json
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import struct
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import numpy as np
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import torch
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from sentencepiece import SentencePieceProcessor
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QK = 32
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GGML_TYPE_Q4_0 = 0
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GGML_TYPE_Q4_1 = 1
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GGML_TYPE_I8 = 2
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GGML_TYPE_I16 = 3
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GGML_TYPE_I32 = 4
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GGML_TYPE_F16 = 5
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GGML_TYPE_F32 = 6
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WTYPES = {
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0: GGML_TYPE_F32,
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1: GGML_TYPE_F16,
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2: GGML_TYPE_Q4_0,
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3: GGML_TYPE_Q4_1,
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}
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GGML_BLCK_SIZE = {
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GGML_TYPE_Q4_0: QK,
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GGML_TYPE_Q4_1: QK,
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GGML_TYPE_I8: 1,
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GGML_TYPE_I16: 1,
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GGML_TYPE_I32: 1,
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GGML_TYPE_F16: 1,
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GGML_TYPE_F32: 1,
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}
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GGML_TYPE_SIZE = {
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GGML_TYPE_Q4_0: 4 + QK//2,
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GGML_TYPE_Q4_1: 4*2 + QK//2,
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GGML_TYPE_I8: 1,
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GGML_TYPE_I16: 2,
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GGML_TYPE_I32: 4,
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GGML_TYPE_F16: 2,
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GGML_TYPE_F32: 4,
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}
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def ggml_nelements(shape):
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r = 1
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for i in shape:
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r *= i
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return r
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def ggml_nbytes(shape, ftype):
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x = ggml_nelements(shape)
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t = WTYPES[ftype]
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x *= GGML_TYPE_SIZE[t]
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x //= GGML_BLCK_SIZE[t]
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return x
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def parse_args():
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parser = argparse.ArgumentParser(description='Convert a LLaMA model checkpoint to a ggml compatible file')
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parser.add_argument('dir_model', help='directory containing the model checkpoint')
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parser.add_argument('ftype', help='file type (0: float32, 1: float16)', type=int, choices=[0, 1], default=1)
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parser.add_argument('vocab_only', help='only write vocab to file', type=int, default=0, nargs='?')
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return parser.parse_args()
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def get_n_parts(dim):
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mappings = {4096: 1, 5120: 2, 6656: 4, 8192: 8}
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n_parts = mappings.get(dim)
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if n_parts is None:
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print(f"Invalid dim: {dim}")
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sys.exit(1)
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print(f"n_parts = {n_parts}\n")
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return n_parts
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def load_hparams_and_tokenizer(dir_model):
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# `dir_model` is something like `models/7B` or `models/7B/`.
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# "tokenizer.model" is expected under model's parent dir.
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# When `dir_model` is a symlink, f"{dir_model}/../tokenizer.model" would not be found.
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# Let's use the model's parent dir directly.
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model_parent_dir = os.path.dirname(os.path.normpath(dir_model))
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fname_hparams = f"{dir_model}/params.json"
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fname_tokenizer = f"{model_parent_dir}/tokenizer.model"
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with open(fname_hparams, "r") as f:
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hparams = json.load(f)
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print(hparams)
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tokenizer = SentencePieceProcessor(fname_tokenizer)
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hparams.update({"vocab_size": tokenizer.vocab_size()})
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return hparams, tokenizer
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def write_header(fout, hparams, ftype):
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keys = ["vocab_size", "dim", "multiple_of", "n_heads", "n_layers"]
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values = [
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0x67676a74, # magic: ggjt in hex
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1, # file version
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*[hparams[key] for key in keys],
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hparams["dim"] // hparams["n_heads"], # rot (obsolete)
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ftype
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]
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fout.write(struct.pack("i" * len(values), *values))
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def write_tokens(fout, tokenizer):
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for i in range(tokenizer.vocab_size()):
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if tokenizer.is_unknown(i):
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text = " \u2047 ".encode()
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elif tokenizer.is_control(i):
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text = b""
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elif tokenizer.is_byte(i):
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piece = tokenizer.id_to_piece(i)
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if len(piece) != 6:
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print(f"Invalid token: {piece}")
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sys.exit(1)
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byte_value = int(piece[3:-1], 16)
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text = struct.pack("B", byte_value)
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else:
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text = tokenizer.id_to_piece(i).replace("\u2581", " ").encode()
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fout.write(struct.pack("i", len(text)))
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fout.write(text)
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fout.write(struct.pack("f", tokenizer.get_score(i)))
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def process_and_write_variables(fout, model, ftype, part_id, n_parts):
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for name, datao in model.items():
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if name.endswith("freqs"):
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continue
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# remove dimensions with a single element
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data = datao.numpy().squeeze()
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partshape = data.shape
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n_dims = len(data.shape)
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assert n_dims in (1, 2)
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print(f"Processing variable: {name} with shape: {partshape} and type: {datao.dtype}")
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# coerce single-dimensional tensors from float16 to float32
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ftype_cur = 1
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if ftype == 0 or n_dims == 1:
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print(" Converting to float32")
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data = data.astype(np.float32)
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ftype_cur = 0
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blck_size = GGML_BLCK_SIZE[WTYPES[ftype_cur]]
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type_size = GGML_TYPE_SIZE[WTYPES[ftype_cur]]
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# determine dimension along which multipart tensor is sharded
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#
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# split_dim 0 regex:
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# - output.*
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# - layers.*.attention.wq.weight
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# - layers.*.attention.wk.weight
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# - layers.*.attention.wv.weight
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# - layers.*.feed_forward.w1.weight
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# - layers.*.feed_forward.w3.weight
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#
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# split_dim 1 regex:
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# - tok_embeddings.*
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# - layers.*.attention.wo.weight
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# - layers.*.feed_forward.w2.weight
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#
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if n_dims > 1:
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split_dim = 1
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if "tok_embeddings" in name:
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split_dim = 1
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elif "layers" in name:
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if "attention.wo.weight" in name:
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split_dim = 1
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elif "feed_forward.w2.weight" in name:
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split_dim = 1
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else:
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split_dim = 0
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elif "output" in name:
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split_dim = 0
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# output tensor header
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fullshape = list(partshape)
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if n_dims > 1:
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fullshape[split_dim] *= n_parts
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sname = name.encode()
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fout.write(struct.pack("iii", n_dims, len(sname), ftype_cur))
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for dim in reversed(fullshape):
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fout.write(struct.pack("i", dim))
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fout.write(sname)
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# ensure tensor data is aligned
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tensor_data_offset = fout.tell()
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while tensor_data_offset % QK != 0:
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fout.write(struct.pack("B", 0))
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tensor_data_offset += 1
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# output unified mappable tensor data
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if n_dims == 1 or n_parts == 1:
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# copy tensor which we thankfully received in one piece
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if part_id == 0:
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data.tofile(fout)
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elif split_dim == 0:
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# reassemble multifile tensor containing some of the rows
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rows_per_chunk = partshape[0]
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current_row = part_id * rows_per_chunk
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bytes_per_row = fullshape[1] // blck_size * type_size
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offset = current_row * bytes_per_row
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fout.seek(tensor_data_offset + offset)
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data.tofile(fout)
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elif split_dim == 1:
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# reassemble multifile tensor containing some of the cols
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cols_per_chunk = partshape[1]
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current_col = part_id * cols_per_chunk
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bytes_per_row = fullshape[1] // blck_size * type_size
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offset_current_col = current_col // blck_size * type_size
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for row in range(partshape[0]):
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offset_row = row * bytes_per_row
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offset = offset_row + offset_current_col
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fout.seek(tensor_data_offset + offset)
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data[row].tofile(fout)
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# advance file position to next tensor
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fout.seek(tensor_data_offset + ggml_nbytes(fullshape, ftype_cur))
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def main():
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args = parse_args()
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dir_model = args.dir_model
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ftype = args.ftype
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ftype_str = ["f32", "f16"]
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hparams, tokenizer = load_hparams_and_tokenizer(dir_model)
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print(args)
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# if only writing vocab to file
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if args.vocab_only:
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fname_model = f"{dir_model}/consolidated.00.pth"
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fname_out = f"{dir_model}/ggml-vocab.bin"
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print(f"Extracting only the vocab from '{fname_model}'\n")
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with open(fname_out, "wb") as fout:
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write_header(fout, hparams, ftype)
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write_tokens(fout, tokenizer)
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print(f"Done. Output file: {fname_out}\n")
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return
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n_parts = get_n_parts(hparams["dim"])
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fname_out = f"{dir_model}/ggml-model-{ftype_str[ftype]}.bin"
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# we output a single file for ggml
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with open(fname_out, "wb") as fout:
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write_header(fout, hparams, ftype)
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write_tokens(fout, tokenizer)
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offset_of_tensors = fout.tell()
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# the tensors we load could be split across multiple files
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for part_id in range(n_parts):
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fout.seek(offset_of_tensors)
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print(f"Processing part {part_id+1} of {n_parts}\n")
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fname_model = f"{dir_model}/consolidated.0{part_id}.pth"
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model = torch.load(fname_model, map_location="cpu")
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process_and_write_variables(fout, model, ftype, part_id, n_parts)
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del model
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print(f"Done. Output file: {fname_out}\n")
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if __name__ == "__main__":
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main()
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