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# Copyright (c) Meta Platforms, Inc. and affiliates. | |
# All rights reserved. | |
# This source code is licensed under the license found in the | |
# LICENSE file in the root directory of this source tree. | |
import time | |
from pathlib import Path | |
import torch | |
import torch.nn as nn | |
import torch.nn.functional as F | |
from tokenizer import get_tokenizer | |
try: | |
from GPTQ import GenericGPTQRunner, InputRecorder | |
from eval import get_task_dict, evaluate, lm_eval | |
except: | |
pass | |
from model import Transformer | |
##### Quantization Primitives ###### | |
def dynamically_quantize_per_channel(x, quant_min, quant_max, target_dtype): | |
# assumes symmetric quantization | |
# assumes axis == 0 | |
# assumes dense memory format | |
# TODO(future): relax ^ as needed | |
# default setup for affine quantization of activations | |
eps = torch.finfo(torch.float32).eps | |
# get min and max | |
min_val, max_val = torch.aminmax(x, dim=1) | |
# calculate scales and zero_points based on min and max | |
# reference: https://fburl.com/code/srbiybme | |
min_val_neg = torch.min(min_val, torch.zeros_like(min_val)) | |
max_val_pos = torch.max(max_val, torch.zeros_like(max_val)) | |
device = min_val_neg.device | |
# reference: https://fburl.com/code/4wll53rk | |
max_val_pos = torch.max(-min_val_neg, max_val_pos) | |
scales = max_val_pos / (float(quant_max - quant_min) / 2) | |
# ensure scales is the same dtype as the original tensor | |
scales = torch.clamp(scales, min=eps).to(x.dtype) | |
zero_points = torch.zeros(min_val_neg.size(), dtype=torch.int64, device=device) | |
# quantize based on qmin/qmax/scales/zp | |
# reference: https://www.internalfb.com/code/fbsource/[8edc275012b1]/fbcode/caffe2/torch/ao/quantization/fx/_decomposed.py?lines=63 | |
x_div = x / scales.unsqueeze(-1) | |
x_round = torch.round(x_div) | |
x_zp = x_round + zero_points.unsqueeze(-1) | |
quant = torch.clamp(x_zp, quant_min, quant_max).to(target_dtype) | |
return quant, scales, zero_points | |
def get_group_qparams(w, n_bit=4, groupsize=128): | |
# needed for GPTQ with padding | |
if groupsize > w.shape[-1]: | |
groupsize = w.shape[-1] | |
assert groupsize > 1 | |
assert w.shape[-1] % groupsize == 0 | |
assert w.dim() == 2 | |
to_quant = w.reshape(-1, groupsize) | |
assert torch.isnan(to_quant).sum() == 0 | |
max_val = to_quant.amax(dim=1, keepdim=True) | |
min_val = to_quant.amin(dim=1, keepdim=True) | |
max_int = 2**n_bit - 1 | |
scales = (max_val - min_val).clamp(min=1e-6) / max_int | |
zeros = min_val + scales * (2 ** (n_bit - 1)) | |
return scales.to(torch.bfloat16).reshape(w.shape[0], -1), zeros.to( | |
torch.bfloat16 | |
).reshape(w.shape[0], -1) | |
def pack_scales_and_zeros(scales, zeros): | |
assert scales.shape == zeros.shape | |
assert scales.dtype == torch.bfloat16 | |
assert zeros.dtype == torch.bfloat16 | |
return ( | |
torch.cat( | |
[ | |
scales.reshape(scales.size(0), scales.size(1), 1), | |
zeros.reshape(zeros.size(0), zeros.size(1), 1), | |
], | |
2, | |
) | |
.transpose(0, 1) | |
.contiguous() | |
) | |
def unpack_scales_and_zeros(scales_and_zeros): | |
assert len(scales_and_zeros.shape) == 3 and scales_and_zeros.shape[2] == 2 | |
assert scales_and_zeros.dtype == torch.float | |
return torch.split(scales_and_zeros.transpose(0, 1), 1, 2) | |
def group_quantize_tensor_from_qparams(w, scales, zeros, n_bit=4, groupsize=128): | |
assert groupsize > 1 | |
# needed for GPTQ single column quantize | |
if groupsize > w.shape[-1] and scales.shape[-1] == 1: | |
groupsize = w.shape[-1] | |
assert w.shape[-1] % groupsize == 0 | |
assert w.dim() == 2 | |
to_quant = w.reshape(-1, groupsize) | |
assert torch.isnan(to_quant).sum() == 0 | |
scales = scales.reshape(-1, 1) | |
zeros = zeros.reshape(-1, 1) | |
min_val = zeros - scales * (2 ** (n_bit - 1)) | |
max_int = 2**n_bit - 1 | |
min_int = 0 | |
w_int32 = ( | |
to_quant.sub(min_val) | |
.div(scales) | |
.round() | |
.clamp_(min_int, max_int) | |
.to(torch.int32) | |
.reshape_as(w) | |
) | |
return w_int32 | |
def group_quantize_tensor(w, n_bit=4, groupsize=128): | |
scales, zeros = get_group_qparams(w, n_bit, groupsize) | |
w_int32 = group_quantize_tensor_from_qparams(w, scales, zeros, n_bit, groupsize) | |
scales_and_zeros = pack_scales_and_zeros(scales, zeros) | |
return w_int32, scales_and_zeros | |
def group_dequantize_tensor_from_qparams( | |
w_int32, scales, zeros, n_bit=4, groupsize=128 | |
): | |
assert groupsize > 1 | |
# needed for GPTQ single column dequantize | |
if groupsize > w_int32.shape[-1] and scales.shape[-1] == 1: | |
groupsize = w_int32.shape[-1] | |
assert w_int32.shape[-1] % groupsize == 0 | |
assert w_int32.dim() == 2 | |
w_int32_grouped = w_int32.reshape(-1, groupsize) | |
scales = scales.reshape(-1, 1) | |
zeros = zeros.reshape(-1, 1) | |
w_dq = ( | |
w_int32_grouped.sub(2 ** (n_bit - 1)).mul(scales).add(zeros).reshape_as(w_int32) | |
) | |
return w_dq | |
def group_dequantize_tensor(w_int32, scales_and_zeros, n_bit=4, groupsize=128): | |
scales, zeros = unpack_scales_and_zeros(scales_and_zeros) | |
return group_dequantize_tensor_from_qparams( | |
w_int32, scales, zeros, n_bit, groupsize | |
) | |
class QuantHandler: | |
def __init__(self, mod): | |
self.mod = mod | |
def create_quantized_state_dict(self) -> "StateDict": | |
pass | |
def convert_for_runtime(self) -> "nn.Module": | |
pass | |
class GPTQQuantHandler(QuantHandler): | |
""" | |
This class implements a GPTQ QuantHandler that can be used to apply GPTQ to a model in concert with the GenericGPTQRunner class. | |
Unlike the base QuantHandler class, the user does not need to implement the create_quantized_state_dict, instead they have to reimplement | |
__init__ such that it defines the functions for the quantization mode. User is expected to reimplement convert_for_runtime. | |
The following functions (which must be defined in __init__) are used to define the quantization mode for both GPTQ and | |
create_quantized_state_dict. Here is a description of each function. | |
get_qparams_func: | |
A function that calculates the quantization qparams for an input tensor. | |
Args: | |
weight: A 2d weight tensor with non-integer dtype. | |
Returns: | |
qparams: it can have any format but will need to be handled by the other defined functions below. | |
quantize_func: | |
A function that applies quantization to an input tensor. It should be noted | |
that this function needs to be able to handle quantizing the entire weight tensor, a single group, | |
or a single column. | |
Args: | |
weight: A 2d weight tensor with non-integer dtype. | |
qparams: the output from get_qparams_func | |
Returns: | |
quantized_weight: A 2d quantized weight tensor (generally with an integer dtype) | |
dequantize_func: | |
A function that dequantizes an input quantized weight tensor. It should be noted | |
that this function needs to be able to handle dequantizing the entire weight tensor, a single group, | |
or a single column. | |
Args: | |
quantized_weight: A 2d quantized weight tensor (generally with an integer dtype) | |
qparams: the output from get_qparams_func | |
Returns: | |
weight: A 2d weight tensor with non-integer dtype. | |
combine_qparams_list_func: | |
A function that combines several qparams into one qparam. | |
Args: | |
qparams_list: a list of qparams objects, each obtained by calling get_qparams_func | |
on a single group from a weight tensor | |
Returns: | |
qparams: an object of the same format as the qparams above. | |
skip_layer_func: | |
A function that determines which linear layers should be skipped during GPTQ | |
Args: | |
weight: A 2d weight tensor with non-integer dtype. | |
Returns: | |
skip: boolean indicating whether layer should be skipped | |
make_names_and_values_dict_func: | |
A function that prepares the qparams and quantized_weight and creates a dictionary indicating how they | |
should be inserted into the state_dict. Generally any packing of the weight and qparams should be done here. | |
Args: | |
quantized_weight: A 2d quantized weight tensor (generally with an integer dtype) | |
qparams: the output from get_qparams_func | |
Returns: | |
names_and_values_dict: a dictionary mapping the name of the parameters of the quantized module to the | |
corresponding quantized weights and qparams. | |
""" | |
def __init__(self): | |
assert self.mod is not None | |
assert self.get_qparams_func is not None | |
assert self.quantize_func is not None | |
assert self.dequantize_func is not None | |
assert self.combine_qparams_list_func is not None | |
assert self.make_names_and_values_dict_func is not None | |
def get_inputs(model, tokenizer, calibration_tasks, calibration_limit, calibration_seq_length, pad_calibration_inputs) -> "MultiInput": | |
input_recorder = InputRecorder( | |
model, | |
tokenizer, | |
calibration_seq_length, | |
pad_calibration_inputs, | |
) | |
try: | |
lm_eval.tasks.initialize_tasks() | |
except: | |
pass | |
task_dict = get_task_dict(calibration_tasks) | |
print("Obtaining GPTQ calibration inputs on: ", calibration_tasks) | |
evaluate( | |
input_recorder, | |
task_dict, | |
limit=calibration_limit, | |
) | |
inputs = input_recorder.get_recorded_inputs() | |
assert inputs is not None, ( | |
f"No inputs were collected, use a task other than {calibration_tasks}, "+ | |
f"use option pad_calibration_inputs, or decrease calibration_sequence_length (currently "+ | |
f"{calibration_seq_length})" | |
) | |
print(f"Obtained {len(inputs[0].values)} calibration samples") | |
return inputs | |
def create_quantized_state_dict( | |
self, | |
tokenizer, | |
blocksize, | |
percdamp, | |
groupsize, | |
calibration_tasks, | |
calibration_limit, | |
calibration_seq_length, | |
pad_calibration_inputs, | |
) -> "StateDict": | |
inputs = GPTQQuantHandler.get_inputs(self.mod, tokenizer, calibration_tasks, calibration_limit, calibration_seq_length, pad_calibration_inputs) | |
print("Tracing model for GPTQ") | |
GPTQ_runner = GenericGPTQRunner( | |
self.mod, | |
inputs, | |
blocksize, | |
percdamp, | |
groupsize, | |
).configure_quantization_mode( | |
self.get_qparams_func, | |
self.quantize_func, | |
self.dequantize_func, | |
self.combine_qparams_list_func, | |
self.make_names_and_values_dict_func, | |
self.skip_layer_func | |
) | |
print("Applying GPTQ to weights") | |
GPTQ_runner.run() | |
return GPTQ_runner.get_quantized_state_dict() | |
def convert_for_runtime(self) -> "nn.Module": | |
pass | |
##### Weight-only int8 per-channel quantized code ###### | |
def replace_linear_weight_only_int8_per_channel(module): | |
for name, child in module.named_children(): | |
if isinstance(child, nn.Linear): | |
setattr(module, name, WeightOnlyInt8Linear(child.in_features, child.out_features)) | |
else: | |
replace_linear_weight_only_int8_per_channel(child) | |
class WeightOnlyInt8QuantHandler: | |
def __init__(self, mod): | |
self.mod = mod | |
def create_quantized_state_dict(self): | |
cur_state_dict = self.mod.state_dict() | |
for fqn, mod in self.mod.named_modules(): | |
if isinstance(mod, torch.nn.Linear): | |
int8_weight, scales, _ = dynamically_quantize_per_channel(mod.weight.float(), -128, 127, torch.int8) | |
cur_state_dict[f"{fqn}.weight"] = int8_weight | |
cur_state_dict[f"{fqn}.scales"] = scales.to(mod.weight.dtype) | |
return cur_state_dict | |
def convert_for_runtime(self): | |
replace_linear_weight_only_int8_per_channel(self.mod) | |
return self.mod | |
class WeightOnlyInt8Linear(torch.nn.Module): | |
__constants__ = ['in_features', 'out_features'] | |
in_features: int | |
out_features: int | |
weight: torch.Tensor | |
def __init__(self, in_features: int, out_features: int, bias: bool = True, | |
device=None, dtype=None) -> None: | |
factory_kwargs = {'device': device, 'dtype': dtype} | |
super().__init__() | |
self.in_features = in_features | |
self.out_features = out_features | |
self.register_buffer("weight", torch.empty((out_features, in_features), dtype=torch.int8)) | |
self.register_buffer("scales", torch.ones(out_features, dtype=torch.bfloat16)) | |
def forward(self, input: torch.Tensor) -> torch.Tensor: | |
return F.linear(input, self.weight.to(dtype=input.dtype)) * self.scales | |
##### weight only int4 per channel groupwise quantized code ###### | |
def prepare_int4_weight_and_scales_and_zeros(weight_bf16, groupsize, inner_k_tiles): | |
weight_int32, scales_and_zeros = group_quantize_tensor( | |
weight_bf16, n_bit=4, groupsize=groupsize | |
) | |
weight_int4pack = torch.ops.aten._convert_weight_to_int4pack(weight_int32, inner_k_tiles) | |
return weight_int4pack, scales_and_zeros | |
def linear_forward_int4(x, weight_int4pack, scales_and_zeros, out_features, groupsize): | |
origin_x_size = x.size() | |
x = x.reshape(-1, origin_x_size[-1]) | |
c = torch.ops.aten._weight_int4pack_mm(x, weight_int4pack, groupsize, scales_and_zeros) | |
new_shape = origin_x_size[:-1] + (out_features,) | |
c = c.reshape(new_shape) | |
return c | |
def _check_linear_int4_k(k, groupsize = 1, inner_k_tiles = 1): | |
return k % groupsize == 0 and k % (inner_k_tiles * 16) == 0 | |
def replace_linear_int4(module, groupsize, inner_k_tiles, padding): | |
for name, child in module.named_children(): | |
if isinstance(child, nn.Linear): | |
if _check_linear_int4_k(child.in_features, groupsize, inner_k_tiles): | |
setattr(module, name, WeightOnlyInt4Linear( | |
child.in_features, child.out_features, bias=False, | |
groupsize=groupsize, inner_k_tiles=inner_k_tiles, padding=False, | |
)) | |
elif padding: | |
setattr(module, name, WeightOnlyInt4Linear( | |
child.in_features, child.out_features, bias=False, | |
groupsize=groupsize, inner_k_tiles=inner_k_tiles, padding=True, | |
)) | |
else: | |
replace_linear_int4(child, groupsize, inner_k_tiles, padding) | |
class WeightOnlyInt4QuantHandler: | |
def __init__(self, mod, groupsize=128, inner_k_tiles=8, padding=True): | |
self.mod = mod | |
self.groupsize = groupsize | |
self.inner_k_tiles = inner_k_tiles | |
self.padding = padding | |
assert groupsize in [32, 64, 128, 256] | |
assert inner_k_tiles in [2, 4, 8] | |
def create_quantized_state_dict(self, use_cuda = True): | |
if use_cuda: | |
device="cuda" | |
else: | |
device="cpu" | |
cur_state_dict = self.mod.state_dict() | |
for fqn, mod in self.mod.named_modules(): | |
if isinstance(mod, torch.nn.Linear): | |
assert not mod.bias | |
out_features = mod.out_features | |
in_features = mod.in_features | |
assert out_features % 8 == 0, "require out_features % 8 == 0" | |
print(f"linear: {fqn}, in={in_features}, out={out_features}") | |
weight = mod.weight.data | |
if not _check_linear_int4_k(in_features, self.groupsize, self.inner_k_tiles): | |
if self.padding: | |
from model import find_multiple | |
import torch.nn.functional as F | |
print(f"warning: {fqn} is padded to satisfy in_features % 1024 == 0") | |
padded_in_features = find_multiple(in_features, 1024) | |
weight = F.pad(weight, pad=(0, padded_in_features - in_features)) | |
else: | |
print(f"warning: {fqn} is skipped, int4 requires that in_features is 32, 64, or is divisible by 1024, " + | |
"and that groupsize and inner_k_tiles*16 evenly divide into it") | |
continue | |
weight_int4pack, scales_and_zeros = prepare_int4_weight_and_scales_and_zeros( | |
weight.to(torch.bfloat16).to(device=device), self.groupsize, self.inner_k_tiles | |
) | |
cur_state_dict[f"{fqn}.weight"] = weight_int4pack.to('cpu') | |
cur_state_dict[f"{fqn}.scales_and_zeros"] = scales_and_zeros.to('cpu') | |
return cur_state_dict | |
def convert_for_runtime(self): | |
replace_linear_int4(self.mod, self.groupsize, self.inner_k_tiles, self.padding) | |
return self.mod | |
class WeightOnlyInt4GPTQQuantHandler(GPTQQuantHandler): | |
def __init__(self, mod, groupsize=128, inner_k_tiles=8, padding=True): | |
from model import find_multiple | |
self.mod = mod | |
self.groupsize = groupsize | |
self.inner_k_tiles = inner_k_tiles | |
self.padding = padding | |
self.get_qparams_func = lambda w: get_group_qparams(w, 4, groupsize) | |
self.quantize_func = lambda w, qparams: \ | |
group_quantize_tensor_from_qparams(w, qparams[0], qparams[1], 4, groupsize) | |
self.dequantize_func = lambda q, qparams: \ | |
group_dequantize_tensor_from_qparams(q, qparams[0], qparams[1], 4, groupsize).float() | |
self.combine_qparams_list_func = lambda qparams_list: \ | |
[torch.cat(x, dim=1) for x in zip(*qparams_list)] | |
# skip unless padding=True or its correctly sized | |
self.skip_layer_func = lambda linear_weight: not ( | |
_check_linear_int4_k(linear_weight.shape[-1], groupsize, inner_k_tiles) or padding | |
) | |
# we need to do the padding here, both for q and the qparams if necessary | |
def make_names_and_values_dict_func(q, qparams): | |
k = q.shape[1] | |
new_k = find_multiple(k, 1024) | |
# how much we need to pad the weight | |
delta_k = new_k - q.shape[1] | |
final_q = torch.ops.aten._convert_weight_to_int4pack(F.pad(q, pad=(0, delta_k)), inner_k_tiles) | |
scales_and_zeros = pack_scales_and_zeros(*qparams) | |
# how many new groups we need for padded weight | |
delta_groups = new_k // groupsize - scales_and_zeros.shape[0] | |
final_s_and_z = F.pad(scales_and_zeros, pad=(0,0,0,0,0, delta_groups), value=1) | |
return {"weight": final_q, "scales_and_zeros": final_s_and_z} | |
self.make_names_and_values_dict_func = make_names_and_values_dict_func | |
super().__init__() | |
def convert_for_runtime(self): | |
replace_linear_int4(self.mod, self.groupsize, self.inner_k_tiles, self.padding) | |
return self.mod | |
class WeightOnlyInt4Linear(torch.nn.Module): | |
__constants__ = ['in_features', 'out_features'] | |
in_features: int | |
out_features: int | |
weight: torch.Tensor | |
def __init__( | |
self, in_features: int, out_features: int, | |
bias=True, device=None, dtype=None, groupsize: int = 128, inner_k_tiles: int = 8, padding: bool = True, | |
) -> None: | |
super().__init__() | |
self.padding = padding | |
if padding: | |
from model import find_multiple | |
self.origin_in_features = in_features | |
in_features = find_multiple(in_features, 1024) | |
self.in_features = in_features | |
self.out_features = out_features | |
assert not bias, "require bias=False" | |
self.groupsize = groupsize | |
self.inner_k_tiles = inner_k_tiles | |
assert out_features % 8 == 0, "require out_features % 8 == 0" | |
assert in_features % (inner_k_tiles * 16) == 0, "require in_features % (innerKTiles * 16) == 0" | |
self.register_buffer( | |
"weight", | |
torch.empty((out_features // 8, in_features // (inner_k_tiles * 16), 32, inner_k_tiles // 2), dtype=torch.int32) | |
) | |
self.register_buffer( | |
"scales_and_zeros", | |
torch.empty((in_features // groupsize, out_features, 2), dtype=torch.bfloat16) | |
) | |
def forward(self, input: torch.Tensor) -> torch.Tensor: | |
input = input.to(torch.bfloat16) | |
if self.padding: | |
import torch.nn.functional as F | |
input = F.pad(input, pad=(0, self.in_features - self.origin_in_features)) | |
return linear_forward_int4( | |
input, | |
self.weight, self.scales_and_zeros, self.out_features, self.groupsize | |
) | |
def quantize( | |
checkpoint_path: Path = Path("checkpoints/meta-llama/Llama-2-7b-chat-hf/model.pth"), | |
mode: str = 'int8', | |
# following arguments only available when setting int4 quantization. | |
groupsize: int = 128, | |
# following arguments only used for GPTQ | |
calibration_tasks: list = ["hellaswag"], | |
calibration_limit: int = 1000, | |
calibration_seq_length: int = 100, | |
pad_calibration_inputs: bool = False, | |
percdamp: float = .01, | |
blocksize: int = 128, | |
label: str = '', | |
) -> None: | |
assert checkpoint_path.is_file(), checkpoint_path | |
device = 'cpu' | |
precision = torch.bfloat16 | |
print("Loading model ...") | |
t0 = time.time() | |
with torch.device('meta'): | |
model = Transformer.from_name(checkpoint_path.parent.name) | |
checkpoint = torch.load(str(checkpoint_path), mmap=True, weights_only=True) | |
model.load_state_dict(checkpoint, assign=True) | |
model = model.to(dtype=precision, device=device) | |
if mode == 'int8': | |
print("Quantizing model weights for int8 weight-only symmetric per-channel quantization") | |
quant_handler = WeightOnlyInt8QuantHandler(model) | |
quantized_state_dict = quant_handler.create_quantized_state_dict() | |
dir_name = checkpoint_path.parent | |
base_name = checkpoint_path.name | |
new_base_name = base_name.replace('.pth', f'{label}int8.pth') | |
elif mode == 'int4': | |
print("Quantizing model weights for int4 weight-only affine per-channel groupwise quantization") | |
quant_handler = WeightOnlyInt4QuantHandler(model, groupsize) | |
quantized_state_dict = quant_handler.create_quantized_state_dict() | |
dir_name = checkpoint_path.parent | |
base_name = checkpoint_path.name | |
new_base_name = base_name.replace('.pth', f"{label}int4.g{groupsize}.pth") | |
elif mode == 'int4-gptq': | |
print("Quantizing model weights for int4 weight-only affine per-channel groupwise quantization using GPTQ...") | |
quant_handler = WeightOnlyInt4GPTQQuantHandler(model, groupsize) | |
tokenizer_path = checkpoint_path.parent / "tokenizer.model" | |
assert tokenizer_path.is_file(), str(tokenizer_path) | |
tokenizer = get_tokenizer(tokenizer_path, checkpoint_path) | |
quantized_state_dict = quant_handler.create_quantized_state_dict( | |
tokenizer, | |
blocksize, | |
percdamp, | |
groupsize, | |
calibration_tasks, | |
calibration_limit, | |
calibration_seq_length, | |
pad_calibration_inputs | |
) | |
dir_name = checkpoint_path.parent | |
base_name = checkpoint_path.name | |
new_base_name = base_name.replace('.pth', f"{label}int4-gptq.g{groupsize}.pth") | |
else: | |
raise ValueError(f"Invalid quantization mode {mode} needs to be one of [int8, int4, int4-gpptq]") | |
quantize_path = dir_name / new_base_name | |
print(f"Writing quantized weights to {quantize_path}") | |
quantize_path.unlink(missing_ok=True) # remove existing file if one already there | |
torch.save(quantized_state_dict, quantize_path) | |
print(f"Quantization complete took {time.time() - t0:.02f} seconds") | |
return | |
if __name__ == '__main__': | |
import argparse | |
parser = argparse.ArgumentParser(description='Quantize a model.') | |
parser.add_argument('--checkpoint_path', type=Path, default=Path("checkpoints/meta-llama/Llama-2-7b-chat-hf/model.pth"), help='Path to the model checkpoint to be quantized.') | |
parser.add_argument('--mode', '-q', type=str, default='int8', choices=['int8', 'int4', 'int4-gptq'], help='type of quantization to perform') | |
parser.add_argument('--groupsize', type=int, default=32, help='Group size for int4 quantization.') | |
parser.add_argument('--calibration_tasks', type=str, nargs='+', default=['wikitext'], help='tasks to do gptq calibration on, if doing gptq') | |
parser.add_argument('--calibration_limit', type=int, default=1000, help='number of samples to use for gptq calibration') | |
parser.add_argument('--calibration_seq_length', type=int, default=100, help='length of sequences to use for gptq calibration') | |
parser.add_argument('--pad_calibration_inputs', type=bool, default=False, help='pads sequences shorter than calibration_seq_length to that length, yielding more calibration inputs but running much slower') | |
parser.add_argument('--percdamp', type=float, default=.01, help='gptq percentage dampening') | |
parser.add_argument('--blocksize', type=int, default=128, help='blocksize for gptq') | |
parser.add_argument('--label', type=str, default='_', help='label to add to output filename') | |
args = parser.parse_args() | |
quantize(args.checkpoint_path, args.mode, args.groupsize, args.calibration_tasks, args.calibration_limit, args.calibration_seq_length, args.pad_calibration_inputs, args.percdamp, args.blocksize, args.label) | |