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import dataclasses

import torch
from torch import Tensor
import torch.nn as nn
from torch.nn import functional as F


@dataclasses.dataclass
class CompressionConfig:
    """Group-wise quantization."""

    num_bits: int
    group_size: int
    group_dim: int
    symmetric: bool
    enabled: bool = True


default_compression_config = CompressionConfig(
    num_bits=8, group_size=256, group_dim=1, symmetric=True, enabled=True
)


class CLinear(nn.Module):
    """Compressed Linear Layer."""

    def __init__(self, weight, bias, device):
        super().__init__()

        self.weight = compress(weight.data.to(device), default_compression_config)
        self.bias = bias

    def forward(self, input: Tensor) -> Tensor:
        weight = decompress(self.weight, default_compression_config)
        return F.linear(input, weight, self.bias)


def compress_module(module, target_device):
    for attr_str in dir(module):
        target_attr = getattr(module, attr_str)
        if type(target_attr) == torch.nn.Linear:
            setattr(
                module,
                attr_str,
                CLinear(target_attr.weight, target_attr.bias, target_device),
            )
    for name, child in module.named_children():
        compress_module(child, target_device)


def compress(tensor, config):
    """Simulate group-wise quantization."""
    if not config.enabled:
        return tensor

    group_size, num_bits, group_dim, symmetric = (
        config.group_size,
        config.num_bits,
        config.group_dim,
        config.symmetric,
    )
    assert num_bits <= 8

    original_shape = tensor.shape
    num_groups = (original_shape[group_dim] + group_size - 1) // group_size
    new_shape = (
        original_shape[:group_dim]
        + (num_groups, group_size)
        + original_shape[group_dim + 1 :]
    )

    # Pad
    pad_len = (group_size - original_shape[group_dim] % group_size) % group_size
    if pad_len != 0:
        pad_shape = (
            original_shape[:group_dim] + (pad_len,) + original_shape[group_dim + 1 :]
        )
        tensor = torch.cat(
            [tensor, torch.zeros(pad_shape, dtype=tensor.dtype, device=tensor.device)],
            dim=group_dim,
        )
    data = tensor.view(new_shape)

    # Quantize
    if symmetric:
        B = 2 ** (num_bits - 1) - 1
        scale = B / torch.max(data.abs(), dim=group_dim + 1, keepdim=True)[0]
        data = data * scale
        data = data.clamp_(-B, B).round_().to(torch.int8)
        return data, scale, original_shape
    else:
        B = 2**num_bits - 1
        mn = torch.min(data, dim=group_dim + 1, keepdim=True)[0]
        mx = torch.max(data, dim=group_dim + 1, keepdim=True)[0]

        scale = B / (mx - mn)
        data = data - mn
        data.mul_(scale)

        data = data.clamp_(0, B).round_().to(torch.uint8)
        return data, mn, scale, original_shape


def decompress(packed_data, config):
    """Simulate group-wise dequantization."""
    if not config.enabled:
        return packed_data

    group_size, num_bits, group_dim, symmetric = (
        config.group_size,
        config.num_bits,
        config.group_dim,
        config.symmetric,
    )

    # Dequantize
    if symmetric:
        data, scale, original_shape = packed_data
        data = data / scale
    else:
        data, mn, scale, original_shape = packed_data
        data = data / scale
        data.add_(mn)

    # Unpad
    pad_len = (group_size - original_shape[group_dim] % group_size) % group_size
    if pad_len:
        padded_original_shape = (
            original_shape[:group_dim]
            + (original_shape[group_dim] + pad_len,)
            + original_shape[group_dim + 1 :]
        )
        data = data.reshape(padded_original_shape)
        indices = [slice(0, x) for x in original_shape]
        return data[indices].contiguous()
    else:
        return data.view(original_shape)